smoothify 0.1.2

Transform pixelated geometries from raster data into smooth natural looking features

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A Python package for smoothing and refining geometries derived from raster data classifications. Smoothify transforms jagged polygons and lines resulting from raster-to-vector conversion into smooth, visually appealing features using an optimized implementation of Chaikin's corner-cutting algorithm.

Problem

Polygons and lines derived from classified raster data (e.g., ML model predictions, spectral indices, or remote sensing classifications) often have unnatural "stair-stepped" or "pixelated" edges that:

• Are visually unappealing in maps and GIS applications
• Can be difficult to work with in downstream vector processing
• Don't represent the real-world features they're meant to depict

Solution

Smoothify applies an optimized implementation of Chaikin's corner-cutting algorithm along with other geometric processing to create smooth, natural-looking features while:

• Preserving the general shape and area of polygons
• Supporting all shapley geometry types
• Handling shapes with interior holes
• Efficiently processing large datasets with multiprocessing

Installation

uv add smoothify

or

pip install smoothify

Quick Start

import geopandas as gpd
from smoothify import smoothify

# Load your polygonized raster data
polygon_gdf = gpd.read_file("path/to/your/polygons.gpkg")

# Apply smoothing (segment_length auto-detected from geometry)
smoothed_gdf = smoothify(
    geom=polygon_gdf,
    smooth_iterations=3,  # More iterations = smoother result
    num_cores=4  # Use parallel processing for large datasets
)

# Or specify segment_length explicitly (generally recommended)
smoothed_gdf = smoothify(
    geom=polygon_gdf,
    segment_length=10.0,  # Use the original raster resolution
    smooth_iterations=3,
    num_cores=4
)

# Save the result
smoothed_gdf.to_file("smoothed_polygons.gpkg")

Examples

Basic Polygon Smoothing

Transform pixelated polygons from raster data into smooth, natural-looking features:

LineString Smoothing

Works perfectly for roads, streams, and other linear features:

Controlling Smoothness with Iterations

The smooth_iterations parameter controls how smooth the result will be:

Merging Adjacent Geometries

When processing multiple adjacent polygons, allowing merge_collection = True produces a combined result:

For more examples, see the examples directory.

General Usage

The smoothify() function accepts three types of input:

1. GeoDataFrame

import geopandas as gpd
from smoothify import smoothify
# By default this will dissolve adjacent polygons before smoothing
gdf = gpd.read_file("polygons.gpkg")
smoothed_gdf = smoothify(
    geom=gdf,
    segment_length=10.0,
    smooth_iterations=3,
    num_cores=4
)

# Dissolve geometries by a specific field before smoothing
# Useful for merging adjacent polygons with the same classification
gdf_with_classes = gpd.read_file("classified_polygons.gpkg")
smoothed_by_class = smoothify(
    geom=gdf_with_classes,
    segment_length=10.0,
    smooth_iterations=3,
    merge_collection=True,
    merge_field="land_type",  # Merge adjacent geometries with same land_type
    num_cores=4
)

2. Single Geometry

from shapely.geometry import Polygon
from smoothify import smoothify

polygon = Polygon([(0, 0), (10, 0), (10, 10), (0, 10)])
smoothed_polygon = smoothify(
    geom=polygon,
    smooth_iterations=3
)

3. List of Geometries or GeometryCollection

from shapely.geometry import Polygon, LineString
from smoothify import smoothify

geometries = [
    Polygon([(0, 0), (10, 0), (10, 10), (0, 10)]),
    LineString([(0, 0), (5, 5), (10, 0)])
]
smoothed = smoothify(
    geom=geometries,
    segment_length=1.0,
    smooth_iterations=3
)

Parameters

Parameter	Type	Default	Description
geom	GeoDataFrame, BaseGeometry, or list[BaseGeometry]	Required	The geometry/geometries to smooth
segment_length	float	None	Resolution of the original raster data in map units. If None (default), automatically detects by finding the minimum segment length (from a data sample). Recommended to specify explicitly when known
smooth_iterations	int	3	Number of Chaikin corner-cutting iterations (typically 3-5). Higher values = smoother output with more vertices
num_cores	int	0	Number of CPU cores for parallel processing (0 = all available cores, 1 = serial)
merge_collection	bool	True	Whether to merge/dissolve adjacent geometries in collections before smoothing
merge_field	str	None	GeoDataFrame only: Column name to use for dissolving geometries. Only valid when merge_collection=True. If None, dissolves all geometries together. If specified, dissolves geometries grouped by the column values
merge_multipolygons	bool	True	Whether to merge adjacent polygons within MultiPolygons before smoothing
preserve_area	bool	True	Whether to restore original area after smoothing via buffering (applies to Polygons only)
area_tolerance	float	0.01	Percentage of original area allowed as error (e.g., 0.01 = 0.01% error = 99.99% preservation). Only affects Polygons when preserve_area=True

How It Works

Smoothify uses an advanced multi-step smoothing pipeline:

1. Adds intermediate vertices along line segments (segmentize)
2. Generates multiple rotated variants (for Polygons) to avoid artifacts
3. Simplifies each variant to remove noise
4. Applies Chaikin corner cutting to smooth
5. Merges all variants via union to eliminate start-point artifacts
6. Applies final smoothing pass
7. Optionally restores original area via buffering (for Polygons)

Performance Considerations

• Parallel Processing: For large GeoDataFrames or collections, use num_cores = 0 to enable parallel processing
• Smoothing Iterations: Values of 3-5 typically provide good results. Higher values create smoother output but increase processing time and vertex count
• Memory Usage: Scales with geometry complexity. The algorithm creates multiple variants during smoothing
• Optimal segment_length: Should match the original raster cell size (pixel size) or be slightly larger for best results

Contributing

Contributions are welcome! Please feel free to submit a Pull Request.

1. Fork the repository
2. Create your feature branch (git checkout -b feature/amazing-feature)
3. Commit your changes (git commit -m 'Add some amazing feature')
4. Push to the branch (git push origin feature/amazing-feature)
5. Open a Pull Request

License

This project is licensed under the MIT License - see the LICENSE file for details.