| import os |
| import cv2 |
| from PIL import Image |
| import numpy as np |
| import segmentation_models as sm |
| from matplotlib import pyplot as plt |
| import random |
|
|
|
|
| from keras import backend as K |
| from keras.models import load_model |
|
|
| import gradio as gr |
|
|
| def jaccard_coef(y_true, y_pred): |
| y_true_flatten = K.flatten(y_true) |
| y_pred_flatten = K.flatten(y_pred) |
| intersection = K.sum(y_true_flatten * y_pred_flatten) |
| final_coef_value = (intersection + 1.0) / (K.sum(y_true_flatten) + K.sum(y_pred_flatten) - intersection + 1.0) |
| return final_coef_value |
| |
| |
| weights = [0.1666, 0.1666, 0.1666, 0.1666, 0.1666, 0.1666] |
| dice_loss = sm.losses.DiceLoss(class_weights = weights) |
| focal_loss = sm.losses.CategoricalFocalLoss() |
| total_loss = dice_loss + (1 * focal_loss) |
|
|
|
|
| satellite_model = load_model('model/satellite-imagery.h5', custom_objects=({'dice_loss_plus_1focal_loss': total_loss, 'jaccard_coef': jaccard_coef})) |
|
|
| def process_input_image(image_source): |
| image = np.expand_dims(image_source, 0) |
|
|
| prediction = satellite_model.predict(image) |
| predicted_image = np.argmax(prediction, axis=3) |
|
|
| predicted_image = predicted_image[0,:,:] |
| predicted_image = predicted_image * 50 |
| return 'Predicted Masked Image', predicted_image |
| |
| |
| my_app = gr.Blocks() |
| |
| with my_app: |
| gr.Markdown("Satellite Image Segmentation Application UI with Gradio") |
| with gr.Tabs(): |
| with gr.TabItem("Select your image"): |
| with gr.Row(): |
| with gr.Column(): |
| img_source = gr.Image(label="Please select source Image", shape=(256, 256)) |
| source_image_loader = gr.Button("Load above Image") |
| with gr.Column(): |
| output_label = gr.Label(label="Image Info") |
| img_output = gr.Image(label="Image Output") |
| source_image_loader.click( |
| process_input_image, |
| [ |
| img_source |
| ], |
| [ |
| output_label, |
| img_output |
| ] |
| ) |
| |
| my_app.launch(debug=True) |
