Metadata-Version: 2.4
Name: libaligator
Version: 0.18.0
Summary: Versatile and efficient framework for constrained trajectory optimization
Requires-Python: >=3.9
License-Expression: BSD-2-Clause
Requires-Dist: cmeel
Requires-Dist: cmeel-boost ~= 1.89.0
Requires-Dist: cmeel-fmt
Requires-Dist: cmeel-mimalloc
Requires-Dist: libcrocoddyl
Requires-Dist: libpinocchio
Requires-Dist: numpy
Provides-Extra: build
Requires-Dist: cmeel-fmt[build] ; extra == "build"
Requires-Dist: cmeel-mimalloc[build] ; extra == "build"
Requires-Dist: libcrocoddyl[build] ; extra == "build"
Requires-Dist: libpinocchio[build] ; extra == "build"
Description-Content-Type: text/markdown

# Aligator

<a href="https://simple-robotics.github.io/aligator/"><img src="https://img.shields.io/badge/docs-online-brightgreen" alt="Documentation"/></a>
[![Conda Version](https://img.shields.io/conda/vn/conda-forge/aligator.svg)](https://anaconda.org/conda-forge/aligator)
[![Ask DeepWiki](https://deepwiki.com/badge.svg)](https://deepwiki.com/Simple-Robotics/aligator)
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<a href="https://repology.org/project/aligator/versions"><img src="https://repology.org/badge/version-for-repo/nix_unstable/aligator.svg"></a>

**Aligator** is an efficient and versatile trajectory optimization library for robotics and beyond.

It can be used for motion generation and planning, optimal estimation, deployment of model-predictive control on complex systems, and much more.

Developing advanced, open-source, and versatile robotics software such as **aligator** takes time and energy while requiring a lot of engineering support.
In recognition of our commitment, we would be grateful if you would quote our papers and software in your publications, software, and research articles.
Please refer to the [Citation section](#citing-aligator) for further details.

## Features

**Aligator** is a C++ library, which provides

* a modelling interface for optimal control problems, node-per-node
* a set of efficient solvers for constrained trajectory optimization
* multiple routines for factorization of linear problems arising in numerical OC
* support for the [pinocchio](https://github.com/stack-of-tasks/pinocchio) rigid-body dynamics library and its analytical derivatives
* an interface to the [Crocoddyl](https://github.com/loco-3d/crocoddyl) trajectory optimization library which can be used as an alternative frontend
* a Python API which can be used for prototyping formulations or even deployment.

**Aligator** provides efficient implementations of the following algorithms for (constrained) trajectory optimization:

* ProxDDP: Proximal Differential Dynamic Programming, detailed in [this paper](https://inria.hal.science/hal-04332348/document)
* FeasibleDDP: Feasible Differential Dynamic Programming, detailed in [this paper](https://inria.hal.science/hal-02294059v1/document)

## Installation

### From Conda

From either conda-forge or [our channel](https://anaconda.org/simple-robotics/aligator).

```bash
conda install -c conda-forge aligator
```

### From source with Pixi

To build **aligator** from source the easiest way is to use [Pixi](https://pixi.sh/latest/#installation).

[Pixi](https://pixi.sh/latest/) is a cross-platform package management tool for developers that
will install all required dependencies in `.pixi` directory.
It's used by our CI agent so you have the guarantee to get the right dependencies.

Run the following command to install dependencies, configure, build and test the project:

```bash
pixi run test
```

The project will be built in the `build` directory.
You can run `pixi shell` and build the project with `cmake` and `ninja` manually.

### Build from source

```bash
git clone https://github.com/Simple-Robotics/aligator --recursive
cmake -DCMAKE_INSTALL_PREFIX=your_install_folder -S . -B build/ && cd build/
cmake --build . -jNCPUS
```

#### Dependencies

* [Eigen3](https://eigen.tuxfamily.org) >= 3.3.7
* [Boost](https://www.boost.org) >= 1.71.0
* OpenMP
* [fmtlib](https://github.com/fmtlib/fmt) >= 10.0.0 | [conda](https://github.com/fmtlib/fmt)
* [mimalloc](https://github.com/microsoft/mimalloc) >= 2.1.0 | [conda](https://github.com/microsoft/mimalloc)
* (optional) [eigenpy](https://github.com/stack-of-tasks/eigenpy)>=3.9.0 | [conda](https://anaconda.org/conda-forge/eigenpy) (Python bindings)
* (optional) [Pinocchio](https://github.com/stack-of-tasks/pinocchio) | [conda](https://anaconda.org/conda-forge/pinocchio)
* (optional) [Crocoddyl](https://github.com/loco-3d/crocoddyl) | [conda](https://anaconda.org/conda-forge/crocoddyl)
* (optional) [example-robot-data](https://github.com/Gepetto/example-robot-data) | [conda](https://anaconda.org/conda-forge/example-robot-data) (required for some examples and benchmarks)
* (optional) [Catch2](https://github.com/catchorg/Catch2) | [conda](https://anaconda.org/conda-forge/catch2) for testing

#### Python dependencies

* [typed-argument-parser](https://github.com/swansonk14/typed-argument-parser)
* [matplotlib](https://matplotlib.org)

### Notes on building

* For developers, add the `-DCMAKE_EXPORT_COMPILE_COMMANDS=1` when working with language servers e.g. clangd.
* To use the Crocoddyl interface, add `-DBUILD_CROCODDYL_COMPAT=ON`
* By default, building the library will instantiate the templates for the `double` scalar type.
* To build against a Conda environment, activate the environment and run `export CMAKE_PREFIX_PATH=$CONDA_PREFIX` before running CMake and use `$CONDA_PREFIX` as your install folder.

## Usage

**aligator** can be used in both C++ (with CMake to create builds) and Python.

Users can refer to [examples](https://github.com/Simple-Robotics/aligator/tree/main/examples) in either language to see how to build a trajectory optimization problem, create a solver instance (with parameters), and solve their problem.

For how to use **aligator** in CMake, including creation of a Python extension module in C++, please refer to the [advanced user's guide](doc/advanced-user-guide.md).

### Aligator parallel & CPU optimizations
Please see the [advanced user's guide](doc/advanced-user-guide.md#using-parallel-aligator--performance-optimization)

## Benchmarking

The repo [aligator-bench](https://github.com/Simple-Robotics/aligator-bench) provides a comparison of aligator against other solvers.

For developer info on benchmarking, see [doc/advanced-user-guide.md](doc/advanced-user-guide.md).

## Citing aligator

To cite **aligator** in your academic research, please use the following bibtex entry:

```bibtex
@misc{aligatorweb,
  author = {Jallet, Wilson and Bambade, Antoine and El Kazdadi, Sarah and Carpentier, Justin and Mansard, Nicolas},
  title = {aligator},
  url = {https://github.com/Simple-Robotics/aligator}
}
```
Please also consider citing the reference paper for the ProxDDP algorithm:

```bibtex
@article{jalletPROXDDPProximalConstrained2025,
  title = {PROXDDP: Proximal Constrained Trajectory Optimization},
  shorttitle = {PROXDDP},
  author = {Jallet, Wilson and Bambade, Antoine and Arlaud, Etienne and {El-Kazdadi}, Sarah and Mansard, Nicolas and Carpentier, Justin},
  year = {2025},
  month = mar,
  journal = {IEEE Transactions on Robotics},
  volume = {41},
  pages = {2605--2624},
  issn = {1941-0468},
  doi = {10.1109/TRO.2025.3554437},
  urldate = {2025-04-04}
}
```

## Contributors

* [Antoine Bambade](https://bambade.github.io/) (Inria): mathematics and algorithms developer
* [Justin Carpentier](https://jcarpent.github.io/) (Inria): project instructor
* [Wilson Jallet](https://manifoldfr.github.io/) (Inria): project lead and principal developer
* [Sarah Kazdadi](https://github.com/sarah-ek/) (Inria): linear algebra czar
* [Quentin Le Lidec](https://quentinll.github.io/) (Inria): feature developer
* [Joris Vaillant](https://github.com/jorisv) (Inria): core developer
* [Nicolas Mansard](https://gepettoweb.laas.fr/index.php/Members/NicolasMansard) (LAAS-CNRS): project coordinator
* [Guilhem Saurel](https://github.com/nim65s) (LAAS-CNRS): core maintainer
* [Fabian Schramm](https://github.com/fabinsch) (Inria): core developer
* [Ludovic De Matteïs](https://github.com/LudovicDeMatteis) (LAAS-CNRS): feature developer
* [Ewen Dantec](https://edantec.github.io/) (Inria): feature developer
* [Antoine Bussy](https://github.com/antoine-bussy) (Aldebaran)
* [Valentin Tordjman--Levavasseur](https://github.com/Tordjx) (Inria): feature developer
* [Louise Manson](https://github.com/LouiseMsn) (Inria): documentation

## Acknowledgments

The development of **aligator** is actively supported by the [Willow team](https://www.di.ens.fr/willow/) [@INRIA](http://www.inria.fr) and the [Gepetto team](http://projects.laas.fr/gepetto/) [@LAAS-CNRS](http://www.laas.fr).

## Associated scientific and technical publications

* E. Ménager, A. Bilger, W. Jallet, J. Carpentier, and C. Duriez, ‘Condensed semi-implicit dynamics for trajectory optimization in soft robotics’, in IEEE International Conference on Soft Robotics (RoboSoft), San Diego (CA), United States: IEEE, Apr. 2024. doi: 10.1109/RoboSoft60065.2024.10521997.
* W. Jallet, N. Mansard, and J. Carpentier, ‘Implicit Differential Dynamic Programming’, in 2022 International Conference on Robotics and Automation (ICRA), Philadelphia, United States: IEEE Robotics and Automation Society, May 2022. doi: 10.1109/ICRA46639.2022.9811647.
* W. Jallet, A. Bambade, N. Mansard, and J. Carpentier, ‘Constrained Differential Dynamic Programming: A primal-dual augmented Lagrangian approach’, in 2022 IEEE/RSJ International Conference on Intelligent Robots and Systems, Kyoto, Japan, Oct. 2022. doi: 10.1109/IROS47612.2022.9981586.
* W. Jallet, A. Bambade, N. Mansard, and J. Carpentier, ‘ProxNLP: a primal-dual augmented Lagrangian solver for nonlinear programming in Robotics and beyond’, in 6th Legged Robots Workshop, Philadelphia, Pennsylvania, United States, May 2022. Accessed: Oct. 10, 2022. [Online]. Available: https://hal.archives-ouvertes.fr/hal-03680510
* W. Jallet, A. Bambade, E. Arlaud, S. El-Kazdadi, N. Mansard, and J. Carpentier, ‘PROXDDP: Proximal Constrained Trajectory Optimization’, IEEE Transactions on Robotics, vol. 41, pp. 2605–2624, Mar. 2025, doi: 10.1109/TRO.2025.3554437.
* S. Kazdadi, J. Carpentier, and J. Ponce, ‘Equality Constrained Differential Dynamic Programming’, presented at the ICRA 2021 - IEEE International Conference on Robotics and Automation, May 2021. Accessed: Sep. 07, 2021. [Online]. Available: https://hal.inria.fr/hal-03184203
* A. Bambade, S. El-Kazdadi, A. Taylor, and J. Carpentier, ‘PROX-QP: Yet another Quadratic Programming Solver for Robotics and beyond’, in Robotics: Science and Systems XVIII, Robotics: Science and Systems Foundation, Jun. 2022. doi: 10.15607/RSS.2022.XVIII.040.
* W. Jallet, E. Dantec, E. Arlaud, N. Mansard, and J. Carpentier, ‘Parallel and Proximal Constrained Linear-Quadratic Methods for Real-Time Nonlinear MPC’, in Proceedings of Robotics: Science and Systems, Delft, Netherlands, Jul. 2024. doi: 10.15607/RSS.2024.XX.002.
* E. Dantec, W. Jallet, and J. Carpentier, ‘From centroidal to whole-body models for legged locomotion: a comparative analysis’, presented at the 2024 IEEE-RAS International Conference on Humanoid Robots, Nancy, France: IEEE, Jul. 2024. [Online]. Available: https://inria.hal.science/hal-04647996
