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from PIL import Image |
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import numpy as np |
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import torch |
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from torchvision import transforms, models |
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from onnx import numpy_helper |
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import os |
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import onnxruntime as rt |
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from matplotlib.colors import hsv_to_rgb |
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import cv2 |
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import gradio as gr |
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import matplotlib.pyplot as plt |
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import matplotlib.patches as patches |
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import pycocotools.mask as mask_util |
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def preprocess(image): |
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ratio = 800.0 / min(image.size[0], image.size[1]) |
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image = image.resize((int(ratio * image.size[0]), int(ratio * image.size[1])), Image.BILINEAR) |
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image = np.array(image)[:, :, [2, 1, 0]].astype('float32') |
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image = np.transpose(image, [2, 0, 1]) |
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mean_vec = np.array([102.9801, 115.9465, 122.7717]) |
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for i in range(image.shape[0]): |
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image[i, :, :] = image[i, :, :] - mean_vec[i] |
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import math |
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padded_h = int(math.ceil(image.shape[1] / 32) * 32) |
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padded_w = int(math.ceil(image.shape[2] / 32) * 32) |
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padded_image = np.zeros((3, padded_h, padded_w), dtype=np.float32) |
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padded_image[:, :image.shape[1], :image.shape[2]] = image |
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image = padded_image |
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return image |
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os.system("wget https://github.com/AK391/models/raw/main/vision/object_detection_segmentation/mask-rcnn/model/MaskRCNN-10.onnx") |
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sess = rt.InferenceSession("MaskRCNN-10.onnx") |
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outputs = sess.get_outputs() |
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classes = [line.rstrip('\n') for line in open('coco_classes.txt')] |
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def display_objdetect_image(image, boxes, labels, scores, masks, score_threshold=0.7): |
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ratio = 800.0 / min(image.size[0], image.size[1]) |
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boxes /= ratio |
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_, ax = plt.subplots(1, figsize=(12,9)) |
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image = np.array(image) |
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for mask, box, label, score in zip(masks, boxes, labels, scores): |
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if score <= score_threshold: |
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continue |
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mask = mask[0, :, :, None] |
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int_box = [int(i) for i in box] |
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mask = cv2.resize(mask, (int_box[2]-int_box[0]+1, int_box[3]-int_box[1]+1)) |
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mask = mask > 0.5 |
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im_mask = np.zeros((image.shape[0], image.shape[1]), dtype=np.uint8) |
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x_0 = max(int_box[0], 0) |
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x_1 = min(int_box[2] + 1, image.shape[1]) |
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y_0 = max(int_box[1], 0) |
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y_1 = min(int_box[3] + 1, image.shape[0]) |
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mask_y_0 = max(y_0 - box[1], 0) |
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mask_y_1 = mask_y_0 + y_1 - y_0 |
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mask_x_0 = max(x_0 - box[0], 0) |
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mask_x_1 = mask_x_0 + x_1 - x_0 |
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im_mask[y_0:y_1, x_0:x_1] = mask[ |
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mask_y_0 : mask_y_1, mask_x_0 : mask_x_1 |
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] |
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im_mask = im_mask[:, :, None] |
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contours, hierarchy = cv2.findContours( |
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im_mask, cv2.RETR_TREE, cv2.CHAIN_APPROX_SIMPLE |
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) |
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image = cv2.drawContours(image, contours, -1, 25, 3) |
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rect = patches.Rectangle((box[0], box[1]), box[2] - box[0], box[3] - box[1], linewidth=1, edgecolor='b', facecolor='none') |
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ax.annotate(classes[label] + ':' + str(np.round(score, 2)), (box[0], box[1]), color='w', fontsize=12) |
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ax.add_patch(rect) |
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ax.imshow(image) |
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plt.axis('off') |
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plt.savefig('out.png', bbox_inches='tight') |
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def inference(img): |
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input_image = Image.open(img) |
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orig_tensor = np.asarray(input_image) |
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input_tensor = preprocess(input_image) |
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output_names = list(map(lambda output: output.name, outputs)) |
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input_name = sess.get_inputs()[0].name |
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boxes, labels, scores, masks = sess.run(output_names, {input_name: input_tensor}) |
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display_objdetect_image(input_image, boxes, labels, scores, masks) |
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return 'out.png' |
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title="Mask R-CNN" |
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description="This model is a real-time neural network for object instance segmentation that detects 80 different classes." |
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examples=[["examplemask-rcnn.jpeg"]] |
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gr.Interface(inference,gr.inputs.Image(type="filepath"),gr.outputs.Image(type="file"),title=title,description=description,examples=examples).launch(enable_queue=True) |