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try: |
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import detectron2 |
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except: |
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import os |
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os.system('pip install git+https://github.com/facebookresearch/detectron2.git') |
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os.system('cd GLEE/glee/models/pixel_decoder/ops && sh mask.sh') |
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import gradio as gr |
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import numpy as np |
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import cv2 |
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import torch |
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from detectron2.config import get_cfg |
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from GLEE.glee.models.glee_model import GLEE_Model |
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from GLEE.glee.config_deeplab import add_deeplab_config |
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from GLEE.glee.config import add_glee_config |
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import torch.nn.functional as F |
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import torchvision |
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import math |
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from obj365_name import categories as OBJ365_CATEGORIESV2 |
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print(f"Is CUDA available: {torch.cuda.is_available()}") |
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if torch.cuda.is_available(): |
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print(f"CUDA device: {torch.cuda.get_device_name(torch.cuda.current_device())}") |
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def box_cxcywh_to_xyxy(x): |
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x_c, y_c, w, h = x.unbind(-1) |
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b = [(x_c - 0.5 * w), (y_c - 0.5 * h), |
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(x_c + 0.5 * w), (y_c + 0.5 * h)] |
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return torch.stack(b, dim=-1) |
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def scribble2box(img): |
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if img.max()==0: |
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return None, None |
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rows = np.any(img, axis=1) |
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cols = np.any(img, axis=0) |
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all = np.any(img,axis=2) |
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R,G,B,A = img[np.where(all)[0][0],np.where(all)[1][0]].tolist() |
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ymin, ymax = np.where(rows)[0][[0, -1]] |
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xmin, xmax = np.where(cols)[0][[0, -1]] |
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return np.array([ xmin,ymin, xmax,ymax]), (R,G,B) |
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def LSJ_box_postprocess( out_bbox, padding_size, crop_size, img_h, img_w): |
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boxes = box_cxcywh_to_xyxy(out_bbox) |
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lsj_sclae = torch.tensor([padding_size[1], padding_size[0], padding_size[1], padding_size[0]]).to(out_bbox) |
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crop_scale = torch.tensor([crop_size[1], crop_size[0], crop_size[1], crop_size[0]]).to(out_bbox) |
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boxes = boxes * lsj_sclae |
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boxes = boxes / crop_scale |
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boxes = torch.clamp(boxes,0,1) |
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scale_fct = torch.tensor([img_w, img_h, img_w, img_h]) |
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scale_fct = scale_fct.to(out_bbox) |
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boxes = boxes * scale_fct |
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return boxes |
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COLORS = [[0.000, 0.447, 0.741], [0.850, 0.325, 0.098], [0.929, 0.694, 0.125], |
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[0.494, 0.184, 0.556], [0.466, 0.674, 0.188], [0.301, 0.745, 0.933], |
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[0.494, 0.000, 0.556], [0.494, 0.000, 0.000], [0.000, 0.745, 0.000], |
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[0.700, 0.300, 0.600],[0.000, 0.447, 0.741], [0.850, 0.325, 0.098]] |
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coco_class_name = ['person', 'bicycle', 'car', 'motorcycle', 'airplane', 'bus', 'train', 'truck', 'boat', 'traffic light', 'fire hydrant', 'stop sign', 'parking meter', 'bench', 'bird', 'cat', 'dog', 'horse', 'sheep', 'cow', 'elephant', 'bear', 'zebra', 'giraffe', 'backpack', 'umbrella', 'handbag', 'tie', 'suitcase', 'frisbee', 'skis', 'snowboard', 'sports ball', 'kite', 'baseball bat', 'baseball glove', 'skateboard', 'surfboard', 'tennis racket', 'bottle', 'wine glass', 'cup', 'fork', 'knife', 'spoon', 'bowl', 'banana', 'apple', 'sandwich', 'orange', 'broccoli', 'carrot', 'hot dog', 'pizza', 'donut', 'cake', 'chair', 'couch', 'potted plant', 'bed', 'dining table', 'toilet', 'tv', 'laptop', 'mouse', 'remote', 'keyboard', 'cell phone', 'microwave', 'oven', 'toaster', 'sink', 'refrigerator', 'book', 'clock', 'vase', 'scissors', 'teddy bear', 'hair drier', 'toothbrush'] |
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OBJ365_class_names = [cat['name'] for cat in OBJ365_CATEGORIESV2] |
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class_agnostic_name = ['object'] |
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if torch.cuda.is_available(): |
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print('use cuda') |
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device = 'cuda' |
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else: |
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print('use cpu') |
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device='cpu' |
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cfg_r50 = get_cfg() |
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add_deeplab_config(cfg_r50) |
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add_glee_config(cfg_r50) |
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conf_files_r50 = 'GLEE/configs/R50.yaml' |
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checkpoints_r50 = torch.load('GLEE_R50_Scaleup10m.pth') |
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cfg_r50.merge_from_file(conf_files_r50) |
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GLEEmodel_r50 = GLEE_Model(cfg_r50, None, device, None, True).to(device) |
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GLEEmodel_r50.load_state_dict(checkpoints_r50, strict=False) |
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GLEEmodel_r50.eval() |
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cfg_swin = get_cfg() |
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add_deeplab_config(cfg_swin) |
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add_glee_config(cfg_swin) |
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conf_files_swin = 'GLEE/configs/SwinL.yaml' |
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checkpoints_swin = torch.load('GLEE_SwinL_Scaleup10m.pth') |
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cfg_swin.merge_from_file(conf_files_swin) |
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GLEEmodel_swin = GLEE_Model(cfg_swin, None, device, None, True).to(device) |
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GLEEmodel_swin.load_state_dict(checkpoints_swin, strict=False) |
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GLEEmodel_swin.eval() |
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pixel_mean = torch.Tensor( [123.675, 116.28, 103.53]).to(device).view(3, 1, 1) |
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pixel_std = torch.Tensor([58.395, 57.12, 57.375]).to(device).view(3, 1, 1) |
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normalizer = lambda x: (x - pixel_mean) / pixel_std |
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inference_size = 800 |
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inference_type = 'resize_shot' |
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size_divisibility = 32 |
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FONT_SCALE = 1.5e-3 |
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THICKNESS_SCALE = 1e-3 |
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TEXT_Y_OFFSET_SCALE = 1e-2 |
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if inference_type != 'LSJ': |
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resizer = torchvision.transforms.Resize(inference_size) |
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def segment_image(img,prompt_mode, categoryname, custom_category, expressiong, results_select, num_inst_select, threshold_select, mask_image_mix_ration, model_selection): |
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if model_selection == 'GLEE-Plus (SwinL)': |
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GLEEmodel = GLEEmodel_swin |
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print('use GLEE-Plus') |
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else: |
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GLEEmodel = GLEEmodel_r50 |
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print('use GLEE-Lite') |
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copyed_img = img['background'][:,:,:3].copy() |
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ori_image = torch.as_tensor(np.ascontiguousarray( copyed_img.transpose(2, 0, 1))) |
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ori_image = normalizer(ori_image.to(device))[None,] |
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_,_, ori_height, ori_width = ori_image.shape |
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if inference_type == 'LSJ': |
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infer_image = torch.zeros(1,3,1024,1024).to(ori_image) |
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infer_image[:,:,:inference_size,:inference_size] = ori_image |
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else: |
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resize_image = resizer(ori_image) |
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image_size = torch.as_tensor((resize_image.shape[-2],resize_image.shape[-1])) |
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re_size = resize_image.shape[-2:] |
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if size_divisibility > 1: |
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stride = size_divisibility |
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padding_size = ((image_size + (stride - 1)).div(stride, rounding_mode="floor") * stride).tolist() |
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infer_image = torch.zeros(1,3,padding_size[0],padding_size[1]).to(resize_image) |
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infer_image[0,:,:image_size[0],:image_size[1]] = resize_image |
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if prompt_mode == 'categories' or prompt_mode == 'expression': |
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if len(results_select)==0: |
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results_select=['box'] |
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if prompt_mode == 'categories': |
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if categoryname =="COCO-80": |
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batch_category_name = coco_class_name |
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elif categoryname =="OBJ365": |
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batch_category_name = OBJ365_class_names |
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elif categoryname =="Custom-List": |
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batch_category_name = custom_category.split(',') |
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else: |
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batch_category_name = class_agnostic_name |
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prompt_list = [] |
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with torch.no_grad(): |
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(outputs,_) = GLEEmodel(infer_image, prompt_list, task="coco", batch_name_list=batch_category_name, is_train=False) |
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topK_instance = max(num_inst_select,1) |
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else: |
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topK_instance = 1 |
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prompt_list = {'grounding':[expressiong]} |
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with torch.no_grad(): |
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(outputs,_) = GLEEmodel(infer_image, prompt_list, task="grounding", batch_name_list=[], is_train=False) |
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mask_pred = outputs['pred_masks'][0] |
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mask_cls = outputs['pred_logits'][0] |
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boxes_pred = outputs['pred_boxes'][0] |
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scores = mask_cls.sigmoid().max(-1)[0] |
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scores_per_image, topk_indices = scores.topk(topK_instance, sorted=True) |
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if prompt_mode == 'categories': |
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valid = scores_per_image>threshold_select |
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topk_indices = topk_indices[valid] |
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scores_per_image = scores_per_image[valid] |
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pred_class = mask_cls[topk_indices].max(-1)[1].tolist() |
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pred_boxes = boxes_pred[topk_indices] |
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boxes = LSJ_box_postprocess(pred_boxes,padding_size,re_size, ori_height,ori_width) |
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mask_pred = mask_pred[topk_indices] |
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pred_masks = F.interpolate( mask_pred[None,], size=(padding_size[0], padding_size[1]), mode="bilinear", align_corners=False ) |
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pred_masks = pred_masks[:,:,:re_size[0],:re_size[1]] |
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pred_masks = F.interpolate( pred_masks, size=(ori_height,ori_width), mode="bilinear", align_corners=False ) |
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pred_masks = (pred_masks>0).detach().cpu().numpy()[0] |
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if 'mask' in results_select: |
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zero_mask = np.zeros_like(copyed_img) |
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for nn, mask in enumerate(pred_masks): |
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mask = mask.reshape(mask.shape[0], mask.shape[1], 1) |
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lar = np.concatenate((mask*COLORS[nn%12][2], mask*COLORS[nn%12][1], mask*COLORS[nn%12][0]), axis = 2) |
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zero_mask = zero_mask+ lar |
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lar_valid = zero_mask>0 |
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masked_image = lar_valid*copyed_img |
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img_n = masked_image*mask_image_mix_ration + np.clip(zero_mask,0,1)*255*(1-mask_image_mix_ration) |
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max_p = img_n.max() |
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img_n = 255*img_n/max_p |
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ret = (~lar_valid*copyed_img)*mask_image_mix_ration + img_n |
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ret = ret.astype('uint8') |
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else: |
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ret = copyed_img |
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if 'box' in results_select: |
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line_width = max(ret.shape) /200 |
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for nn,(classid, box) in enumerate(zip(pred_class,boxes)): |
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x1,y1,x2,y2 = box.long().tolist() |
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RGB = (COLORS[nn%12][2]*255,COLORS[nn%12][1]*255,COLORS[nn%12][0]*255) |
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cv2.rectangle(ret, (x1,y1), (x2,y2), RGB, math.ceil(line_width) ) |
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if prompt_mode == 'categories' or (prompt_mode == 'expression' and 'expression' in results_select ): |
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if prompt_mode == 'categories': |
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label = '' |
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if 'name' in results_select: |
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label += batch_category_name[classid] |
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if 'score' in results_select: |
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label += str(scores_per_image[nn].item())[:4] |
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else: |
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label = expressiong |
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if len(label)==0: |
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continue |
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height, width, _ = ret.shape |
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FONT = cv2.FONT_HERSHEY_COMPLEX |
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label_width, label_height = cv2.getTextSize(label, FONT, min(width, height) * FONT_SCALE, math.ceil(min(width, height) * THICKNESS_SCALE))[0] |
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cv2.rectangle(ret, (x1,y1), (x1+label_width,(y1 -label_height) - int(height * TEXT_Y_OFFSET_SCALE)), RGB, -1) |
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cv2.putText( |
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ret, |
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label, |
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(x1, y1 - int(height * TEXT_Y_OFFSET_SCALE)), |
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fontFace=FONT, |
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fontScale=min(width, height) * FONT_SCALE, |
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thickness=math.ceil(min(width, height) * THICKNESS_SCALE), |
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color=(255,255,255), |
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) |
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ret = ret.astype('uint8') |
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return ret |
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else: |
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topK_instance = 1 |
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copyed_img = img['background'][:,:,:3].copy() |
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bbox_list = [scribble2box(layer) for layer in img['layers'] ] |
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visual_prompt_list = [] |
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visual_prompt_RGB_list = [] |
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for mask, (box,RGB) in zip(img['layers'], bbox_list): |
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if box is None: |
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continue |
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if prompt_mode=='box': |
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fakemask = np.zeros_like(copyed_img[:,:,0]) |
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x1 ,y1 ,x2, y2 = box |
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fakemask[ y1:y2, x1:x2 ] = 1 |
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fakemask = fakemask>0 |
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elif prompt_mode=='point': |
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fakemask = np.zeros_like(copyed_img[:,:,0]) |
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H,W = fakemask.shape |
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x1 ,y1 ,x2, y2 = box |
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center_x, center_y = (x1+x2)//2, (y1+y2)//2 |
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fakemask[ center_y-H//40:center_y+H//40, center_x-W//40:center_x+W//40 ] = 1 |
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fakemask = fakemask>0 |
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elif prompt_mode=='scribble': |
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fakemask = mask[:,:,-1] |
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fakemask = fakemask>0 |
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fakemask = torch.from_numpy(fakemask).unsqueeze(0).to(ori_image) |
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if inference_type == 'LSJ': |
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infer_visual_prompt = torch.zeros(1,1024,1024).to(ori_image) |
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infer_visual_prompt[:,:inference_size,:inference_size] = fakemask |
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else: |
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resize_fakemask = resizer(fakemask) |
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if size_divisibility > 1: |
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infer_visual_prompt = torch.zeros(1,padding_size[0],padding_size[1]).to(resize_fakemask) |
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infer_visual_prompt[:,:image_size[0],:image_size[1]] = resize_fakemask |
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visual_prompt_list.append( infer_visual_prompt>0 ) |
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visual_prompt_RGB_list.append(RGB) |
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mask_results_list = [] |
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for visual_prompt in visual_prompt_list: |
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prompt_list = {'spatial':[visual_prompt]} |
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with torch.no_grad(): |
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(outputs,_) = GLEEmodel(infer_image, prompt_list, task="coco", batch_name_list=['object'], is_train=False, visual_prompt_type=prompt_mode ) |
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mask_pred = outputs['pred_masks'][0] |
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mask_cls = outputs['pred_logits'][0] |
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boxes_pred = outputs['pred_boxes'][0] |
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scores = mask_cls.sigmoid().max(-1)[0] |
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scores_per_image, topk_indices = scores.topk(topK_instance, sorted=True) |
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pred_class = mask_cls[topk_indices].max(-1)[1].tolist() |
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pred_boxes = boxes_pred[topk_indices] |
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boxes = LSJ_box_postprocess(pred_boxes,padding_size,re_size, ori_height,ori_width) |
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mask_pred = mask_pred[topk_indices] |
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pred_masks = F.interpolate( mask_pred[None,], size=(padding_size[0], padding_size[1]), mode="bilinear", align_corners=False ) |
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pred_masks = pred_masks[:,:,:re_size[0],:re_size[1]] |
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pred_masks = F.interpolate( pred_masks, size=(ori_height,ori_width), mode="bilinear", align_corners=False ) |
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pred_masks = (pred_masks>0).detach().cpu().numpy()[0] |
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mask_results_list.append(pred_masks) |
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zero_mask = np.zeros_like(copyed_img) |
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for mask,RGB in zip(mask_results_list,visual_prompt_RGB_list): |
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mask = mask.reshape(mask.shape[-2], mask.shape[-1], 1) |
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lar = np.concatenate((mask*RGB[0], mask*RGB[1],mask*RGB[2]), axis = 2) |
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zero_mask = zero_mask+ lar |
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lar_valid = zero_mask>0 |
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masked_image = lar_valid*copyed_img |
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img_n = masked_image*mask_image_mix_ration + np.clip(zero_mask,0,255)*(1-mask_image_mix_ration) |
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max_p = img_n.max() |
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img_n = 255*img_n/max_p |
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ret = (~lar_valid*copyed_img)*mask_image_mix_ration + img_n |
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ret = ret.astype('uint8') |
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return ret |
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def visual_prompt_preview(img, prompt_mode): |
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copyed_img = img['background'][:,:,:3].copy() |
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bbox_list = [scribble2box(layer) for layer in img['layers'] ] |
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zero_mask = np.zeros_like(copyed_img) |
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for mask, (box,RGB) in zip(img['layers'], bbox_list): |
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if box is None: |
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continue |
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if prompt_mode=='box': |
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fakemask = np.zeros_like(copyed_img[:,:,0]) |
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x1 ,y1 ,x2, y2 = box |
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fakemask[ y1:y2, x1:x2 ] = 1 |
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fakemask = fakemask>0 |
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elif prompt_mode=='point': |
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fakemask = np.zeros_like(copyed_img[:,:,0]) |
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H,W = fakemask.shape |
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x1 ,y1 ,x2, y2 = box |
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center_x, center_y = (x1+x2)//2, (y1+y2)//2 |
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fakemask[ center_y-H//40:center_y+H//40, center_x-W//40:center_x+W//40 ] = 1 |
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fakemask = fakemask>0 |
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else: |
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fakemask = mask[:,:,-1] |
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fakemask = fakemask>0 |
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mask = fakemask.reshape(fakemask.shape[0], fakemask.shape[1], 1) |
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lar = np.concatenate((mask*RGB[0], mask*RGB[1],mask*RGB[2]), axis = 2) |
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zero_mask = zero_mask+ lar |
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img_n = copyed_img + np.clip(zero_mask,0,255) |
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max_p = img_n.max() |
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ret = 255*img_n/max_p |
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ret = ret.astype('uint8') |
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return ret |
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with gr.Blocks() as demo: |
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gr.Markdown('# GLEE: General Object Foundation Model for Images and Videos at Scale') |
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gr.Markdown('## [Paper](https://arxiv.org/abs/2312.09158) - [Project Page](https://glee-vision.github.io) - [Code](https://github.com/FoundationVision/GLEE) ') |
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|
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gr.Markdown( |
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'**The functionality demonstration demo app of GLEE. Select a Tab for image or video tasks. Image tasks includes arbitrary vocabulary object detection&segmentation, any form of object name or object caption detection, referring expression comprehension, and interactive segmentation. Video tasks add object tracking functionality based on image tasks.**' |
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) |
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with gr.Tab("Image task"): |
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with gr.Row(): |
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with gr.Column(): |
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|
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img_input = gr.ImageEditor() |
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model_select = gr.Dropdown( |
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["GLEE-Lite (R50)", "GLEE-Plus (SwinL)"], value = "GLEE-Plus (SwinL)" , multiselect=False, label="Model", |
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) |
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with gr.Row(): |
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with gr.Column(): |
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prompt_mode_select = gr.Radio(["point", "scribble", "box", "categories", "expression"], label="Prompt", value= "categories" , info="What kind of prompt do you want to use?") |
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category_select = gr.Dropdown( |
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["COCO-80", "OBJ365", "Custom-List", "Class-Agnostic"], value = "COCO-80" , multiselect=False, label="Categories", info="Choose an existing category list or class-agnostic" |
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) |
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custom_category = gr.Textbox( |
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label="Custom Category", |
|
info="Input custom category list, seperate by ',' ", |
|
lines=1, |
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value="dog, cat, car, person", |
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) |
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input_expressiong = gr.Textbox( |
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label="Expression", |
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info="Input any description of an object in the image ", |
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lines=2, |
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value="the red car", |
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) |
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|
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with gr.Group(): |
|
with gr.Accordion("Text based detection usage",open=False): |
|
gr.Markdown( |
|
'Press the "Detect & Segment" button directly to try the effect using the COCO category.<br />\ |
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GLEE supports three kind of object perception methods: category list, textual description, and class-agnostic.<br />\ |
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1.Select an existing category list from the "Categories" dropdown, like COCO or OBJ365, or customize your own list.<br />\ |
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2.Enter arbitrary object name in "Custom Category", or choose the expression model and describe the object in "Expression Textbox" for single object detection only.<br />\ |
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3.For class-agnostic mode, choose "Class-Agnostic" from the "Categories" dropdown.' |
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) |
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with gr.Accordion("Interactive segmentation usage",open=False): |
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gr.Markdown( |
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'For interactive segmentation:<br />\ |
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1.Draw points, boxes, or scribbles on the canvas for multiclass segmentation; use separate layers for different objects, adding layers with a "+" sign.<br />\ |
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2.Point mode accepts a single point only; multiple points default to the centroid, so use boxes or scribbles for larger objects.<br />\ |
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3.After drawing, click green "√" on the right side of the image to preview the prompt visualization; the segmentation mask follows the chosen prompt colors.' |
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) |
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img_showbox = gr.Image(label="visual prompt area preview") |
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with gr.Column(): |
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image_segment = gr.Image(label="detection and segmentation results") |
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with gr.Accordion("Try More Visualization Options"): |
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results_select = gr.CheckboxGroup(["box", "mask", "name", "score", "expression"], value=["box", "mask", "name", "score"], label="Shown Results", info="The results shown on image") |
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num_inst_select = gr.Slider(1, 50, value=15, step=1, label="Num of topK instances for category based detection", info="Choose between 1 and 50 for better visualization") |
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threshold_select = gr.Slider(0, 1, value=0.2, label="Confidence Threshold", info="Choose threshold ") |
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mask_image_mix_ration = gr.Slider(0, 1, value=0.45, label="Image Brightness Ratio", info="Brightness between image and colored masks ") |
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image_button = gr.Button("Detect & Segment") |
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img_input.change(visual_prompt_preview, inputs = [img_input,prompt_mode_select] , outputs = img_showbox) |
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image_button.click(segment_image, inputs=[img_input, prompt_mode_select, category_select, custom_category,input_expressiong, results_select, num_inst_select, threshold_select, mask_image_mix_ration,model_select], outputs=image_segment) |
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with gr.Tab("Video task"): |
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with gr.Row(): |
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gr.Markdown( |
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'# Due to computational resource limitations, support for video tasks is being processed and is expected to be available within a week.' |
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) |
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video_input = gr.Image() |
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video_button = gr.Button("Segment&Track") |
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if __name__ == '__main__': |
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demo.launch(inbrowser=True,share=True) |
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