# SpiPy [![PyPI version](https://badge.fury.io/py/spires.svg)](https://pypi.org/project/spires/) [![Documentation Status](https://readthedocs.org/projects/spipy/badge/?version=latest)](https://spipy.readthedocs.io/en/latest/?badge=latest) [![Build and Test](https://github.com/NiklasPhabian/SpiPy/workflows/Build%20and%20Test/badge.svg)](https://github.com/NiklasPhabian/SpiPy/actions) [![Python 3.9-3.14](https://img.shields.io/badge/python-3.9--3.14-blue.svg)](https://github.com/NiklasPhabian/SpiPy) [![License: MIT](https://img.shields.io/badge/License-MIT-yellow.svg)](https://opensource.org/licenses/MIT) **[📦 View Source on GitHub](https://github.com/NiklasPhabian/SpiPy)** | **[📖 Documentation](https://spipy.readthedocs.io)** | **[🐛 Report Issues](https://github.com/NiklasPhabian/SpiPy/issues)** SpiPy is a Python implementation of [SPIRES](https://ieeexplore.ieee.org/document/9290428) (Snow Property Inversion From Remote Sensing), originally implemented in MATLAB ([SPIRES GitHub repository](https://github.com/edwardbair/SPIRES)). ## Overview SPIRES retrieves snow properties (grain size, dust concentration, fractional snow-covered area) from satellite multispectral imagery by inverting reflectance spectra using lookup tables generated from Mie-scattering theory. **Key features:** - Hybrid Python/C++ implementation for performance (3000x speedup over pure Python) - Support for MODIS, Sentinel-2, and Landsat data - SWIG bindings for optimized interpolation and optimization routines - NLopt-based nonlinear optimization ## Installation ### Quick Install (PyPI) ```bash pip install spires ``` **Note:** Pre-built binary wheels are available for Linux and macOS (Python 3.9-3.14). For other platforms or to build from source, see below. ### Install from Source **Important:** Use conda-forge for all dependencies. The apt version of `nlopt` does not include required C++ headers. ```bash # Install build tools and nlopt (required) conda install -c conda-forge swig gxx gcc nlopt # Install all dependencies (recommended) conda install -c conda-forge numpy h5py scipy xarray netCDF4 gdal geopandas matplotlib tox sphinx dask jupyterlab pyproj ``` ### Git LFS This repository uses Git LFS for test data. Install Git LFS before cloning: ```bash # macOS brew install git-lfs # Linux sudo apt install git-lfs # Initialize git lfs install ``` ### Build and Install ```bash # Build SWIG extensions python3 setup.py build_ext --inplace # Install package pip install . # Or install with optional dependencies pip install ".[dev,test,docs]" ``` ## Usage See the `examples/` folder for Jupyter notebooks with detailed use cases. Basic usage: ```python import spires # Load lookup table interpolator = spires.LutInterpolator( lut_file='tests/data/lut_sentinel2b_b2to12_3um_dust.mat' ) # Process imagery to get fractional snow-covered area fsca = spires.get_fsca(...) ``` ## Development ### Building Wheels Build a wheel for the active Python interpreter: ```bash pip install build python -m build --wheel ``` Build wheels for multiple Python versions using tox: ```bash tox -e py39,py310,py311,py312 ``` **Note:** When using pyenv, wheels for Python 3.9 may incorrectly build for x86 instead of arm64 on M1 Macs. Use a conda environment to build correctly. ### Building C++ Extensions Manually The setuptools build process handles SWIG bindings automatically. To build manually: ```bash cd spires make ``` Or specify paths explicitly: ```bash NUMPY_INCLUDE=$(python -c "import numpy; print(numpy.get_include())") g++ -shared -o spires_module.so spires.cpp -I$NUMPY_INCLUDE ``` ### Testing Run doctests: ```bash pytest --doctest-modules ``` ### Documentation Install documentation dependencies: ```bash pip install ".[docs]" ``` Build documentation: ```bash cd doc/ make html ``` ## Lookup Tables and Test Data ### Lookup Tables Simulated Mie-scattering snow reflectance lookup tables are available on Zenodo: [![DOI](https://zenodo.org/badge/DOI/10.5281/zenodo.18701286.svg)](https://doi.org/10.5281/zenodo.18701286) - **MODIS**: `LUT_MODIS.mat` (537 MB) - **Sentinel-2**: `lut_sentinel2b_b2to12_3um_dust.mat` (70 MB) Download using the helper script: ```bash python scripts/download_test_data.py --luts ``` Or download directly: ```bash curl -L -o LUT_MODIS.mat https://zenodo.org/records/18701286/files/LUT_MODIS.mat curl -L -o lut_sentinel2b_b2to12_3um_dust.mat https://zenodo.org/records/18701286/files/lut_sentinel2b_b2to12_3um_dust.mat ``` **Note:** The Sentinel-2 LUT is also included in the repository via Git LFS. Landsat lookup tables are planned. ### Test Data Full-resolution test imagery for validation is available on Zenodo: [![DOI](https://zenodo.org/badge/DOI/10.5281/zenodo.18704072.svg)](https://doi.org/10.5281/zenodo.18704072) - **Sentinel-2 reflectance**: `sentinel_r.nc` (1.4 GB, 921×1347 pixels) - **Background reflectance**: `sentinel_r0.nc` (705 MB) Small subsets suitable for CI/testing are included in the repository via Git LFS. See [tests/data/README.md](tests/data/README.md) for details. ## Performance The C++ optimizations provide significant speedups over pure Python: **Interpolation:** 3000x faster (1.07 ms → 309 ns) - Pure Python RegularGridInterpolator: 1.07 ms - Vectorized Python: 143 μs - SWIG C++ (vectorized): 5.58 μs - SWIG C++ (index lookup): 309 ns **Spectrum Difference:** 1000x faster (1.1 ms → 1 μs) - Pure Python: 1.1 ms - With optimized interpolator: 3.8 μs - C++ implementation: 1 μs **Full Optimization:** 3000x faster (165 ms → 43 μs) - Scipy optimization: 165 ms - With optimized interpolator: 4.94 ms - With C++ spectrum difference: 3.5 ms - NLopt in C++: 43 μs ## Known Issues - SLSQP solver doesn't work in the C++ implementation; using COBYLA instead - SWIG interpolator and scipy's RegularGridInterpolator behave differently when coordinates aren't linspace - COBYLA in scipy can't set `rhobeg` per dimension individually, requiring problem scaling ## Roadmap - [ ] Optimize inversion for single location over multiple timesteps (keep R_0 constant) - [ ] Support xarray inputs for interpolator and spectra - [ ] Add Landsat lookup tables - [ ] Improve cloud masking workflows ## License See LICENSE file for details. ## Citation If you use this software, please cite the algorithm paper, software implementation, and any datasets you use: **Algorithm:** ```bibtex @article{bair2021spires, title={Snow Property Inversion From Remote Sensing (SPIReS): A Generalized Multispectral Unmixing Approach With Examples From MODIS and Landsat 8 OLI}, author={Bair, E. H. and Stillinger, T. and Dozier, J.}, journal={IEEE Transactions on Geoscience and Remote Sensing}, volume={59}, number={9}, pages={7270--7284}, year={2021}, doi={10.1109/TGRS.2020.3040328} } ``` **Software:** ```bibtex @software{bair2026spipy, title={SpiPy: Python implementation of SPIRES snow property inversion}, author={Bair, Edward H. and Griessbaum, Niklas}, year={2026}, url={https://github.com/NiklasPhabian/SpiPy}, version={0.2.2}, doi={10.5281/zenodo.XXXXXXX}, note={DOI will be updated after Zenodo release. See CITATION.cff for full metadata} } ``` **Lookup Tables (if used):** ```bibtex @dataset{bair2026spires_luts, author = {Bair, Edward and Dozier, Jeff}, title = {{SPIRES} Snow Reflectance Lookup Tables}, year = 2026, publisher = {Zenodo}, doi = {10.5281/zenodo.18701286}, url = {https://doi.org/10.5281/zenodo.18701286} } ``` **Test Data (if used):** ```bibtex @dataset{griessbaum2026sentinel2_testdata, author = {Griessbaum, Niklas}, title = {Sentinel-2 reflectance data for testing the {SpiPy} implementation of the {SPIRES} algorithm}, year = 2026, publisher = {Zenodo}, doi = {10.5281/zenodo.18704072}, url = {https://doi.org/10.5281/zenodo.18704072} } ``` Alternatively, see [CITATION.cff](CITATION.cff) or use GitHub's "Cite this repository" feature. ## Funding Development of this software was supported by: **Contract:** W913E523C0002 **Program:** "Climate and natural hazards, snow-covered and mountain environment sensing research" **Sponsor:** Broad Agency Announcement Program, Cold Regions Research and Engineering Laboratory **Monitored by:** U.S. Army Engineer Research and Development Center, Hanover, NH 03755 **Distribution Statement:** Approved for public release; distribution is unlimited.