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import os |
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os.environ["CUDA_DEVICE_ORDER"] = "PCI_BUS_ID" |
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import gradio as gr |
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import torch |
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import cv2 |
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import numpy as np |
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from preprocess import unsharp_masking |
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import time |
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from sklearn.cluster import KMeans |
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device = "cuda" if torch.cuda.is_available() else "cpu" |
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def ordenar_arquivos(img, modelo): |
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ori = img.copy() |
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img = cv2.cvtColor(img, cv2.COLOR_BGR2GRAY) |
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h, w = img.shape |
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img_out = preprocessamento(img, modelo) |
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return img_out, h, w, img, ori |
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def preprocessamento(img, modelo='SE-RegUNet 4GF'): |
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img = cv2.resize(img, (512, 512)) |
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img = unsharp_masking(img).astype(np.uint8) |
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if modelo == 'AngioNet' or modelo == 'UNet3+': |
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img = np.float32((img - img.min()) / (img.max() - img.min() + 1e-6)) |
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img_out = np.expand_dims(img, axis=0) |
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elif modelo == 'SE-RegUNet 4GF': |
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clahe1 = cv2.createCLAHE(clipLimit=2.0, tileGridSize=(8, 8)) |
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clahe2 = cv2.createCLAHE(clipLimit=8.0, tileGridSize=(8, 8)) |
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image1 = clahe1.apply(img) |
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image2 = clahe2.apply(img) |
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img = np.float32((img - img.min()) / (img.max() - img.min() + 1e-6)) |
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image1 = np.float32((image1 - image1.min()) / (image1.max() - image1.min() + 1e-6)) |
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image2 = np.float32((image2 - image2.min()) / (image2.max() - image2.min() + 1e-6)) |
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img_out = np.stack((img, image1, image2), axis=0) |
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else: |
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clahe1 = cv2.createCLAHE(clipLimit=2.0, tileGridSize=(8, 8)) |
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image1 = clahe1.apply(img) |
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image1 = np.float32((image1 - image1.min()) / (image1.max() - image1.min() + 1e-6)) |
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img_out = np.stack((image1,) * 3, axis=0) |
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return img_out |
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def processar_imagem_de_entrada(img, modelo, pipe): |
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img = img.copy() |
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pipe = pipe.to(device).eval() |
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start = time.time() |
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img, h, w, ori_gray, ori = ordenar_arquivos(img, modelo) |
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img = torch.FloatTensor(img).unsqueeze(0).to(device) |
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with torch.no_grad(): |
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if modelo == 'AngioNet': |
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img = torch.cat([img, img], dim=0) |
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logit = np.round(torch.softmax(pipe.forward(img), dim=1).detach().cpu().numpy()[0, 0]).astype(np.uint8) |
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spent = time.time() - start |
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spent = f"{spent:.3f} segundos" |
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if h != 512 or w != 512: |
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logit = cv2.resize(logit, (h, w)) |
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logit = logit.astype(bool) |
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img_out = ori.copy() |
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img_out[logit, 0] = 255 |
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return spent, img_out |
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models = { |
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'SE-RegUNet 4GF': torch.jit.load('./model/SERegUNet4GF.pt'), |
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'SE-RegUNet 16GF': torch.jit.load('./model/SERegUNet16GF.pt'), |
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'AngioNet': torch.jit.load('./model/AngioNet.pt'), |
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'EffUNet++ B5': torch.jit.load('./model/EffUNetppb5.pt'), |
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'Reg-SA-UNet++': torch.jit.load('./model/RegSAUnetpp.pt'), |
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'UNet3+': torch.jit.load('./model/UNet3plus.pt'), |
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} |
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def processar_imagem_de_entrada_wrapper(img, modelo): |
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model = models[modelo] |
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spent, img_out = processar_imagem_de_entrada(img, modelo, model) |
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kmeans = KMeans(n_clusters=2, random_state=0) |
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flattened_img = img_out[:, :, 0].reshape((-1, 1)) |
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kmeans.fit(flattened_img) |
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labels = kmeans.labels_ |
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area_0 = np.sum(labels == 0) |
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area_1 = np.sum(labels == 1) |
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has_disease_flag = area_1 >= 200 |
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if has_disease_flag: |
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status_doenca = "Sim" |
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else: |
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status_doenca = "Não" |
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if has_disease_flag: |
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explanation = "A máquina detectou uma possível doença nos vasos sanguíneos." |
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else: |
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explanation = "A máquina não detectou nenhuma doença nos vasos sanguíneos." |
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return spent, img_out, status_doenca, explanation |
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my_app = gr.Interface( |
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fn=processar_imagem_de_entrada_wrapper, |
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inputs=[ |
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gr.inputs.Image(label="Angiograma:", shape=(512, 512)), |
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gr.inputs.Dropdown(['SE-RegUNet 4GF', 'SE-RegUNet 16GF', 'AngioNet', 'EffUNet++ B5', 'Reg-SA-UNet++', 'UNet3+'], label='Modelo', default='SE-RegUNet 4GF'), |
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], |
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outputs=[ |
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gr.outputs.Label(label="Tempo decorrido"), |
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gr.outputs.Image(type="numpy", label="Imagem de Saída"), |
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gr.outputs.Label(label="Possui Doença?"), |
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gr.outputs.Label(label="Explicação"), |
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], |
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title="Segmentação de Angiograma Coronariano", |
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description="Esta aplicação segmenta angiogramas coronarianos usando modelos de segmentação pré-treinados.", |
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theme="default", |
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layout="vertical", |
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allow_flagging=False, |
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) |
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my_app.launch() |
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