import numpy as np import gradio as gr from PIL import Image import cv2 from skimage import color from sklearn.cluster import KMeans from typing import Tuple f = "view.png" img = Image.open(f) img = np.array(img)[..., :3] def proc(img: np.ndarray) -> Tuple[np.ndarray, np.ndarray]: assert img.shape[-1] == 3 k_size = 11 sigma = 11 blurred = cv2.GaussianBlur(img, (k_size, k_size), sigma) blurred_small = cv2.resize(blurred, (80, 80)) labs = color.rgb2lab(blurred_small) lab_vectors = labs.reshape(-1, 3) num_colors = 5 num_bins = 10 km = KMeans(n_clusters=num_colors) km.fit(lab_vectors) centroid_labs = km.cluster_centers_ # N x (L, a, b) centroid_labs = np.array( sorted(centroid_labs, key=lambda x: x[1] ** 2 + x[2] ** 2) ) # sort by L centroid_ls = ( np.arange(0, 100, num_bins).reshape(1, num_bins, 1).repeat(num_colors, axis=0) ) centroid_abs = centroid_labs[:, np.newaxis, 1:].repeat(num_bins, axis=1) centroid_labs = np.concatenate([centroid_ls, centroid_abs], axis=-1).reshape( num_colors, num_bins, 3 ) unique_indices = [0] + [ i for i in range(1, num_colors) if np.linalg.norm(centroid_labs[i] - centroid_labs[i - 1]) > 10 ] centroid_labs = centroid_labs[unique_indices, :, :] centroid_rgbs = (color.lab2rgb(centroid_labs) * 255).astype(np.uint8) centroid_rgb_vis = cv2.resize( centroid_rgbs, (int(img.shape[0] / num_colors * num_bins), img.shape[0]), interpolation=cv2.INTER_NEAREST, ) return centroid_rgb_vis demo = gr.Interface(fn=proc, inputs="image", outputs="image") if __name__ == "__main__": demo.launch()