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Hamilton is a lightweight Python library for directed acyclic graphs (DAGs) of data transformations. Your DAG is portable; it runs anywhere Python runs, whether it's a script, notebook, Airflow pipeline, FastAPI server, etc. Your DAG is expressive; Hamilton has extensive features to define and modify the execution of a DAG (e.g., data validation, experiment tracking, remote execution).
To create a DAG, write regular Python functions that specify their dependencies with their parameters. As shown below, it results in readable code that can always be visualized. Hamilton loads that definition and automatically builds the DAG for you!
B()
and C()
refer to function A
via their parameters
Hamilton brings modularity and structure to any Python application moving data: ETL pipelines, ML workflows, LLM applications, RAG systems, BI dashboards, and the Hamilton UI allows you to automatically visualize, catalog, and monitor execution.
Hamilton is great for DAGs, but if you need loops or conditional logic to create an LLM agent or a simulation, take a look at our sister library Burr π€ .
Hamilton supports Python 3.8+. We include the optional visualization
dependency to display our Hamilton DAG. For visualizations, Graphviz needs to be installed on your system separately.
pip install "sf-hamilton[visualization]"
To use the Hamilton UI, install the ui
and sdk
dependencies.
pip install "sf-hamilton[ui,sdk]"
To try Hamilton in the browser, visit www.tryhamilton.dev
Data teams write code to deliver business value, but few have the resources to standardize practices and provide quality assurance. Moving from proof-of-concept to production and cross-function collaboration (e.g., data science, engineering, ops) remain challenging for teams, big or small. Hamilton is designed to help throughout a project's lifecycle:
Separation of concerns. Hamilton separates the DAG "definition" and "execution" which lets data scientists focus on solving problems and engineers manage production pipelines.
Effective collaboration. The Hamilton UI provides a shared interface for teams to inspect results and debug failures throughout the development cycle.
Low-friction dev to prod. Use @config.when()
to modify your DAG between execution environments instead of error-prone if/else
feature flags. The notebook extension prevents the pain of migrating code from a notebook to a Python module.
Portable transformations. Your DAG is independent of infrastructure or orchestration, meaning you can develop and debug locally and reuse code across contexts (local, Airflow, FastAPI, etc.).
Maintainable DAG definition. Hamilton automatically builds the DAG from a single line of code whether it has 10 or 1000 nodes. It can also assemble multiple Python modules into a pipeline, encouraging modularity.
Expressive DAGs. Function modifiers are a unique feature to keep your code DRY and reduce the complexity of maintaining large DAGs. Other frameworks inevitably lead to code redundancy or bloated functions.
Built-in coding style. The Hamilton DAG is defined using Python functions, encouraging modular, easy-to-read, self-documenting, and unit testable code.
Data and schema validation. Decorate functions with @check_output
to validate output properties, and raise warnings or exceptions. Add the SchemaValidator()
adapter to automatically inspect dataframe-like objects (pandas, polars, Ibis, etc.) to track and validate their schema.
Built for plugins. Hamilton is designed to play nice with all tools and provides the right abstractions to create custom integrations with your stack. Our lively community will help you build what you need!
You can track the execution of your Hamilton DAG in the Hamilton UI. It automatically populates a data catalog with lineage / tracing and provides execution observability to inspect results and debug errors. You can run it as a local server or a self-hosted application using Docker.
DAG catalog, automatic dataset profiling, and execution tracking
To use the Hamilton UI, install the dependencies (see Installation
section) and start the server with
hamilton ui
On the first connection, create a username
and a new project (the project_id
should be 1
).
Track your Hamilton DAG by creating a HamiltonTracker
object with your username
and project_id
and adding it to your Builder
. Now, your DAG will appear in the UI's catalog and all executions will be tracked!
from hamilton import driver
from hamilton_sdk.adapters import HamiltonTracker
import my_dag
# use your `username` and `project_id`
tracker = HamiltonTracker(
username="my_username",
project_id=1,
dag_name="hello_world",
)
# adding the tracker to the `Builder` will add the DAG to the catalog
dr = (
driver.Builder()
.with_modules(my_dag)
.with_adapters(tracker) # add your tracker here
.build()
)
# executing the `Driver` will track results
dr.execute(["C"])
π See the official documentation to learn about the core concepts of Hamilton.
π¨βπ« Consult the examples on GitHub to learn about specific features or integrations with other frameworks.
π° The DAGWorks blog includes guides about how to build a data platform and narrative tutorials.
πΊ Find video tutorials on the DAGWorks YouTube channel
π£ Reach out via the Hamilton Slack community for help and troubleshooting
Hamilton is not an orchestrator (you might not need one), nor a feature store (but you can use it to build one!). Its purpose is to help you structure and manage data transformations. If you know dbt, Hamilton does for Python what dbt does for SQL.
Another way to frame it is to think about the different layers of a data stack. Hamilton is at the asset layer. It helps you organize data transformations code (the expression layer), manage changes, and validate & test data.
Layer | Purpose | Example Tools |
---|---|---|
Orchestration | Operational system for the creation of assets | Airflow, Metaflow, Prefect, Dagster |
Asset | Organize expressions into meaningful units (e.g., dataset, ML model, table) | Hamilton, dbt, dlt, SQLMesh, Burr |
Expression | Language to write data transformations | pandas, SQL, polars, Ibis, LangChain |
Execution | Perform data transformations | Spark, Snowflake, DuckDB, RAPIDS |
Data | Physical representation of data, inputs and outputs | S3, Postgres, file system, Snowflake |
See our page on Why use Hamilton? and framework code comparisons for more information.
Hamilton is released under the BSD 3-Clause Clear License. See LICENSE for details.
We're very supportive of changes by new contributors, big or small! Make sure to discuss potential changes by creating an issue or commenting on an existing one before opening a pull request. Good first contributions include creating an example or an integration with your favorite Python library!
To contribute, checkout our contributing guidelines, our developer setup guide, and our Code of Conduct.
Hamilton was started at Stitch Fix before the original creators founded DAGWorks Inc! The library is battle-tested and has been supporting production use cases since 2019.
Read more about the origin story.
Thanks to our awesome community and their active involvement in the Hamilton library.
Nils Olsson, MichaΕ Siedlaczek, Alaa Abedrabbo, Shreya Datar, Baldo Faieta, Anwar Brini, Gourav Kumar, Amos Aikman, Ankush Kundaliya, David Weselowski, Peter Robinson, Seth Stokes, Louis Maddox, Stephen Bias, Anup Joseph, Jan Hurst, Flavia Santos, Nicolas Huray, Manabu Niseki, Kyle Pounder, Alex Bustos, Andy Day, Alexander Cai, Nils MΓΌller-Wendt, Paul Larsen, Kemal Eren, Jernej Frank, Noah Ridge
We'd appreciate citing Hamilton by referencing one of the following:
@inproceedings{DBLP:conf/vldb/KrawczykI22,
title = {Hamilton: a modular open source declarative paradigm for high level
modeling of dataflows},
author = {Stefan Krawczyk and Elijah ben Izzy},
editor = {Satyanarayana R. Valluri and Mohamed Za{\"{\i}}t},
booktitle = {1st International Workshop on Composable Data Management Systems,
CDMS@VLDB 2022, Sydney, Australia, September 9, 2022},
year = {2022},
url = {https://cdmsworkshop.github.io/2022/Proceedings/ShortPapers/Paper6\_StefanKrawczyk.pdf},
timestamp = {Wed, 19 Oct 2022 16:20:48 +0200},
biburl = {https://dblp.org/rec/conf/vldb/KrawczykI22.bib},
bibsource = {dblp computer science bibliography, https://dblp.org}
}
@inproceedings{CEURWS:conf/vldb/KrawczykIQ22,
title = {Hamilton: enabling software engineering best practices for data transformations via generalized dataflow graphs},
author = {Stefan Krawczyk and Elijah ben Izzy and Danielle Quinn},
editor = {Cinzia Cappiello and Sandra Geisler and Maria-Esther Vidal},
booktitle = {1st International Workshop on Data Ecosystems co-located with 48th International Conference on Very Large Databases (VLDB 2022)},
pages = {41--50},
url = {https://ceur-ws.org/Vol-3306/paper5.pdf},
year = {2022}
}