Metadata-Version: 2.4
Name: quadfit
Version: 1.0.0
Summary: Fork of QuadrilateralFitter rewritten in C. QuadrilateralFitter is an efficient and easy-to-use Python library for fitting irregular quadrilaterals from irregular polygons or any noisy data.
Author-email: Krzysztof Mizgała <krzysztof@mizgala.pl>
License-Expression: MIT
Project-URL: Homepage, https://github.com/KMChris/quadfit
Keywords: quadrilateral,fitter,polygon,shape analysis,geometry
Classifier: Development Status :: 5 - Production/Stable
Classifier: Programming Language :: Python
Classifier: Programming Language :: Python :: 3
Classifier: Programming Language :: Python :: 3 :: Only
Classifier: Programming Language :: C
Classifier: Operating System :: OS Independent
Classifier: Intended Audience :: Developers
Classifier: Intended Audience :: Science/Research
Classifier: Intended Audience :: Education
Classifier: Topic :: Software Development :: Libraries
Classifier: Topic :: Software Development :: Libraries :: Python Modules
Classifier: Topic :: Scientific/Engineering :: Mathematics
Requires-Python: >=3.9
Description-Content-Type: text/markdown
License-File: LICENSE
Requires-Dist: shapely
Requires-Dist: numpy
Requires-Dist: scipy
Dynamic: license-file

# QuadrilateralFitter
This project is a fork of the original [QuadrilateralFitter](https://github.com/Eric-Canas/quadrilateral-fitter) project.
Modifications by Krzysztof Mizgała (2025). Licensed under the MIT License.
The original Python code has been rewritten in C to boost performance.

<img alt="QuadrilateralFitter Logo" title="QuadrilateralFitter" src="https://raw.githubusercontent.com/KMChris/quadfit/main/resources/logo.png" width="20%" align="left"> **QuadrilateralFitter** is an efficient and easy-to-use library for fitting irregular quadrilaterals from polygons or point clouds.

**QuadrilateralFitter** helps you find that four corners polygon that **best approximates** your noisy data or detection, so you can apply further processing steps like: _perspective correction_ or _pattern matching_, without worrying about noise or non-expected vertex.

Optimal **Fitted Quadrilateral** is the smallest area quadrilateral that contains all the points inside a given polygon.

## Installation

You can install **QuadrilateralFitter** with pip:

```bash
pip install quadfit
```

## Usage

There is only one line you need to use **QuadrilateralFitter**:

```python
from quadrilateral_fitter import QuadrilateralFitter

# Fit an input polygon of N sides
fitted_quadrilateral = QuadrilateralFitter(polygon=your_noisy_polygon).fit()
```

<div align="center">
  <img alt="Fitting Example 1" title="Fitting Example 1" src="https://raw.githubusercontent.com/KMChris/quadfit/main/resources/basic_example_1.png" height="250px">
         &nbsp;
  <img alt="Fitting Example 2" title="Fitting Example 2" src="https://raw.githubusercontent.com/KMChris/quadfit/main/resources/basic_example_2.png" height="250px">&nbsp;
</div>

If your application can accept fitted quadrilateral to don't strictly include all points within input polygon, you can get the tighter quadrilateral shown as `Initial Guess` with:

```python
fitted_quadrilateral = QuadrilateralFitter(polygon=your_noisy_polygon).tight_quadrilateral
```

## API Reference

### QuadrilateralFitter(polygon)

Initialize the **QuadrilateralFitter** instance..

- `polygon`: **np.ndarray | tuple | list | shapely.Polygon**. List of the polygon coordinates. It must be a list of coordinates, in the format `XY`, shape (N, 2).

### QuadrilateralFitter.fit(simplify_polygons_larger_than = 10):
- `simplify_polygons_larger_than`: **int | None**. List of the polygon coordinates. It must be a list of coordinates, in the format `XY`, shape (N, 2). If a number is specified, the method will make a preliminar _Douglas-Peucker_ simplification of the internally used _Convex Hull_ if it has more than `simplify_polygons_larger_than vertices`. This will speed up the process, but may lead to a sub-optimal quadrilateral approximation. Default: 10.

**Returns**: **tuple[tuple[float, float], tuple[float, float], tuple[float, float], tuple[float, float]]**: A `tuple` containing the four `XY` coordinates of the fitted cuadrilateral. This quadrilateral will minimize the **IoU** (Intersection Over Union) with the input _polygon_, while containing all its points inside. If your use case can allow loosing points from the input polygon, you can read the `QuadrilateralFitter.tight_polygon` property to obtain a tighter quadrilateral.


## Real Case Example

Let's simulate a real case scenario where we detect a noisy polygon from a form that we know should be a perfect rectangle (only deformed by perspective).

```python
import numpy as np
import cv2

image = cv2.cvtColor(cv2.imread('./resources/input_sample.jpg'), cv2.COLOR_BGR2RGB)   

# Save the Ground Truth corners
true_corners = np.array([[50., 100.], [370., 0.], [421., 550.], [0., 614.], [50., 100.]], dtype=np.float32)

# Generate a simulated noisy detection
sides = [np.linspace([x1, y1], [x2, y2], 20) + np.random.normal(scale=10, size=(20, 2))
         for (x1, y1), (x2, y2) in zip(true_corners[:-1], true_corners[1:])]
noisy_corners = np.concatenate(sides, axis=0)

# To simplify, we will clip the corners to be within the image
noisy_corners[:, 0] = np.clip(noisy_corners[:, 0], a_min=0., a_max=image.shape[1])
noisy_corners[:, 1] = np.clip(noisy_corners[:, 1], a_min=0., a_max=image.shape[0])
```
<div align="center">
<img alt="Input Sample" title="Input Sample" src="https://raw.githubusercontent.com/KMChris/quadfit/main/resources/input_noisy_detection.png" height="300px" align="center">
</div>

And now, let's run **QuadrilateralFitter** to find the quadrilateral that best approximates our noisy detection (without leaving points outside).

```python
from quadrilateral_fitter import QuadrilateralFitter

# Define the fitter (we want to keep it for reading internal variables later)
fitter = QuadrilateralFitter(polygon=noisy_corners)

# Get the fitted quadrilateral that contains all the points inside the input polygon
fitted_quadrilateral = np.array(fitter.fit(), dtype=np.float32)
# If you wanna to get a tighter mask, less likely to contain points outside the real quadrilateral, 
# but that cannot ensure to always contain all the points within the input polygon, you can use:
tight_quadrilateral = np.array(fitter.tight_quadrilateral, dtype=np.float32)

# To show the plot of the fitting process
fitter.plot()
```

<div align="center">
  <img alt="Fitting Process" title="Fitting Process" src="https://raw.githubusercontent.com/KMChris/quadfit/main/resources/fitting_process.png" height="300px">
         &nbsp; &nbsp;
  <img alt="Fitted Quadrilateral" title="Fitted Quadrilateral" src="https://raw.githubusercontent.com/KMChris/quadfit/main/resources/fitted_quadrilateral.png" height="300px">&nbsp;
</div>

Finally, for use cases like this, we could use fitted quadrilaterals to apply a perspective correction to the image, so we can get a visual insight of the results.

```python
# Generate the destiny points for the perspective correction by adjusting it to a perfect rectangle
h, w = image.shape[:2]

for quadrilateral in (fitted_quadrilateral, tight_quadrilateral):
    # Cast it to a numpy for agile manipulation
    quadrilateral = np.array(quadrilateral, dtype=np.float32)

    # Get the bounding box of the fitted quadrilateral
    min_x, min_y = np.min(quadrilateral, axis=0)
    max_x, max_y = np.max(quadrilateral, axis=0)

    # Define the destiny points for the perspective correction
    destiny_points = np.array(((min_x, min_y), (max_x, min_y),
                               (max_x, max_y), (min_x, max_y)), dtype=np.float32)

    # Calculate the homography matrix from the quadrilateral to the rectangle
    homography_matrix, _ = cv2.findHomography(srcPoints=quadrilateral, dstPoints=rect_points)
    # Warp the image using the homography matrix
    warped_image = cv2.warpPerspective(src=image, M=homography_matrix, dsize=(w, h))
```

<div align="center">
  <img alt="Input Segmentation" title="Input Segmentation" src="https://raw.githubusercontent.com/KMChris/quadfit/main/resources/input_segmentation.png" height="230px">
  <img alt="Corrected Perspective Fitted" title="Corrected Perspective Fitted" src="https://raw.githubusercontent.com/KMChris/quadfit/main/resources/corrected_perspective_fitted.png" height="230px">
  <img alt="Corrected Perspective Tight" title="Corrected Perspective Tight" src="https://raw.githubusercontent.com/KMChris/quadfit/main/resources/corrected_perspective_tight.png" height="230px">
</div>
