import os from PIL import Image, ImageOps import random import cv2 from diffusers.models import AutoencoderKL import gradio as gr import numpy as np from segment_anything import build_sam, SamPredictor from tqdm import tqdm from transformers import CLIPModel, AutoProcessor, CLIPVisionModel import torch from torchvision import transforms from diffusion import create_diffusion from model import UNet2DDragConditionModel import spaces TITLE = '''DragAPart: Learning a Part-Level Motion Prior for Articulated Objects''' DESCRIPTION = """
Try DragAPart yourself to manipulate your favorite articulated objects in seconds!
""" INSTRUCTION = ''' 2 steps to get started: - Upload an image of an articulated object. - Add one or more drags on the object to specify the part-level interactions. How to add drags: - To add a drag, first click on the starting point of the drag, then click on the ending point of the drag, on the Input Image (leftmost). - You can add up to 10 drags, but we suggest one drag per part. - After every click, the drags will be visualized on the Image with Drags (second from left). - If the last drag is not completed (you specified the starting point but not the ending point), it will simply be ignored. - Have fun dragging! Then, you will be prompted to verify the object segmentation. Once you confirm that the segmentation is decent, the output image will be generated in seconds! ''' PREPROCESS_INSTRUCTION = ''' Segmentation is needed if it is not already provided through an alpha channel in the input image. You don't need to tick this box if you have chosen one of the example images. If you have uploaded one of your own images, it is very likely that you will need to tick this box. You should verify that the preprocessed image is object-centric (i.e., clearly contains a single object) and has white background. ''' def center_and_square_image(pil_image_rgba, drags): image = pil_image_rgba alpha = np.array(image)[:, :, 3] # Extract the alpha channel cy, cx = np.round(np.mean(np.nonzero(alpha), axis=1)).astype(int) side_length = max(image.width, image.height) padded_image = ImageOps.expand( image, (side_length // 2, side_length // 2, side_length // 2, side_length // 2), fill=(255, 255, 255, 255) ) left, top = cx, cy new_drags = [] for d in drags: x, y = d new_x, new_y = (x + side_length // 2 - cx) / side_length, (y + side_length // 2 - cy) / side_length new_drags.append((new_x, new_y)) # Crop or pad the image as needed to make it centered around (cx, cy) image = padded_image.crop((left, top, left + side_length, top + side_length)) # Resize the image to 256x256 image = image.resize((256, 256), Image.Resampling.LANCZOS) return image, new_drags def sam_init(): sam_checkpoint = os.path.join(os.path.dirname(__file__), "ckpts", "sam_vit_h_4b8939.pth") predictor = SamPredictor(build_sam(checkpoint=sam_checkpoint).to("cuda")) return predictor def model_init(): model_checkpoint = os.path.join(os.path.dirname(__file__), "ckpts", "drag-a-part-final.pt") model = UNet2DDragConditionModel.from_pretrained_sd( os.path.join(os.path.dirname(__file__), "ckpts", "stable-diffusion-v1-5"), unet_additional_kwargs=dict( sample_size=32, flow_original_res=False, input_concat_dragging=False, attn_concat_dragging=True, use_drag_tokens=False, single_drag_token=False, one_sided_attn=True, flow_in_old_version=False, ), load=False, ) model.load_state_dict(torch.load(model_checkpoint, map_location="cpu")["model"]) return model.to("cuda") sam_predictor = sam_init() model = model_init() vae = AutoencoderKL.from_pretrained("stabilityai/sd-vae-ft-ema").to('cuda') clip_model = CLIPModel.from_pretrained("openai/clip-vit-base-patch32").to('cuda') clip_vit = CLIPVisionModel.from_pretrained("openai/clip-vit-large-patch14").to('cuda') image_processor = AutoProcessor.from_pretrained("openai/clip-vit-base-patch32") diffusion = create_diffusion(timestep_respacing="", learn_sigma=False) @spaces.GPU(duration=10) def sam_segment(input_image, drags, foreground_points=None): image = np.asarray(input_image) sam_predictor.set_image(image) with torch.no_grad(): masks_bbox, _, _ = sam_predictor.predict( point_coords=foreground_points if foreground_points is not None else None, point_labels=np.ones(len(foreground_points)) if foreground_points is not None else None, multimask_output=True ) out_image = np.zeros((image.shape[0], image.shape[1], 4), dtype=np.uint8) out_image[:, :, :3] = image out_image[:, :, 3] = masks_bbox[-1].astype(np.uint8) * 255 torch.cuda.empty_cache() out_image, new_drags = center_and_square_image(Image.fromarray(out_image, mode="RGBA"), drags) return out_image, new_drags def get_point(img, sel_pix, evt: gr.SelectData): sel_pix.append(evt.index) points = [] img = np.array(img) height = img.shape[0] arrow_width_large = 7 * height // 256 arrow_width_small = 3 * height // 256 circle_size = 5 * height // 256 with_alpha = img.shape[2] == 4 for idx, point in enumerate(sel_pix): if idx % 2 == 1: cv2.circle(img, tuple(point), circle_size, (0, 0, 255, 255) if with_alpha else (0, 0, 255), -1) else: cv2.circle(img, tuple(point), circle_size, (255, 0, 0, 255) if with_alpha else (255, 0, 0), -1) points.append(tuple(point)) if len(points) == 2: cv2.arrowedLine(img, points[0], points[1], (0, 0, 0, 255) if with_alpha else (0, 0, 0), arrow_width_large) cv2.arrowedLine(img, points[0], points[1], (255, 255, 0, 255) if with_alpha else (0, 0, 0), arrow_width_small) points = [] return img if isinstance(img, np.ndarray) else np.array(img) def clear_drag(): return [] def preprocess_image(img, chk_group, drags): if img is None: gr.Warning("No image is specified. Please specify an image before preprocessing.") return None, drags if drags is None or len(drags) == 0: foreground_points = None else: foreground_points = np.array([drags[i] for i in range(0, len(drags), 2)]) if len(drags) == 0: gr.Warning("No drags are specified. We recommend first specifying the drags before preprocessing.") new_drags = drags if "Preprocess with Segmentation" in chk_group: img_np = np.array(img) rgb_img = img_np[..., :3] img, new_drags = sam_segment( rgb_img, drags, foreground_points=foreground_points, ) else: new_drags = [(d[0] / img.width, d[1] / img.height) for d in drags] img = np.array(img).astype(np.float32) processed_img = img[..., :3] * img[..., 3:] / 255. + 255. * (1 - img[..., 3:] / 255.) image_pil = Image.fromarray(processed_img.astype(np.uint8), mode="RGB") processed_img = image_pil.resize((256, 256), Image.LANCZOS) return processed_img, new_drags def single_image_sample( x_cond, x_cond_clip, rel, cfg_scale, x_cond_extra, drags, hidden_cls, num_steps=50, ): z = torch.randn(2, 4, 32, 32).to("cuda") # Prepare input for classifer-free guidance rel = torch.cat([rel, rel], dim=0).to("cuda") x_cond = torch.cat([x_cond, x_cond], dim=0).to("cuda") x_cond_clip = torch.cat([x_cond_clip, x_cond_clip], dim=0).to("cuda") x_cond_extra = torch.cat([x_cond_extra, x_cond_extra], dim=0).to("cuda") drags = torch.cat([drags, drags], dim=0).to("cuda") hidden_cls = torch.cat([hidden_cls, hidden_cls], dim=0).to("cuda") model_kwargs = dict( x_cond=x_cond, x_cond_extra=x_cond_extra, cfg_scale=cfg_scale, hidden_cls=hidden_cls, drags=drags, ) # Denoising step_delta = diffusion.num_timesteps // num_steps for i in tqdm(range(num_steps)): with torch.no_grad(): samples = diffusion.p_sample( model.forward_with_cfg, z, torch.Tensor([diffusion.num_timesteps - 1 - step_delta * i]).long().to("cuda").repeat(z.shape[0]), clip_denoised=False, model_kwargs=model_kwargs, )["pred_xstart"] if i != num_steps - 1: z = diffusion.q_sample( samples, torch.Tensor([diffusion.num_timesteps - 1 - step_delta * i]).long().to("cuda").repeat(z.shape[0]) ) samples, _ = samples.chunk(2, dim=0) if vae is not None: with torch.no_grad(): images = vae.decode(samples / 0.18215).sample else: images = samples return ((images + 1)[0].permute(1, 2, 0) * 127.5).cpu().numpy().clip(0, 255).astype(np.uint8) @spaces.GPU(duration=20) def generate_image(img_cond, seed, cfg_scale, drags_list): if img_cond is None: gr.Warning("Please preprocess the image first.") return None with torch.no_grad(): torch.manual_seed(seed) np.random.seed(seed) torch.cuda.manual_seed(seed) torch.cuda.manual_seed_all(seed) random.seed(seed) pixels_cond = transforms.ToTensor()(img_cond.astype(np.float32) / 127.5 - 1).unsqueeze(0).to("cuda") cond_pixel_preprocessed_for_clip = image_processor( images=Image.fromarray(img_cond), return_tensors="pt" ).pixel_values.to("cuda") with torch.no_grad(): x_cond = vae.encode(pixels_cond).latent_dist.sample().mul_(0.18215) cond_clip_features = clip_model.get_image_features(cond_pixel_preprocessed_for_clip) cls_embedding = torch.stack( clip_vit(pixel_values=cond_pixel_preprocessed_for_clip, output_hidden_states=True).hidden_states, dim=1 )[:, :, 0] # dummies rel = torch.zeros(1, 4).to("cuda") x_cond_extra = torch.zeros(1, 3, 32, 32).to("cuda") drags = torch.zeros(1, 10, 4).to("cuda") for i in range(0, len(drags_list), 2): if i + 1 == len(drags_list): gr.Warning("The ending point of the last drag is not specified. The last drag is ignored.") break idx = i // 2 drags[0, idx, 0], drags[0, idx, 1], drags[0, idx, 2], drags[0, idx, 3] = \ drags_list[i][0], drags_list[i][1], drags_list[i + 1][0], drags_list[i + 1][1] if idx == 9: break return single_image_sample( x_cond, cond_clip_features, rel, cfg_scale, x_cond_extra, drags, cls_embedding, num_steps=50, ) with gr.Blocks(title=TITLE) as demo: gr.Markdown("# " + DESCRIPTION) with gr.Row(): gr.Markdown(INSTRUCTION) drags = gr.State(value=[]) with gr.Row(variant="panel"): with gr.Column(scale=1): input_image = gr.Image( interactive=True, type='pil', image_mode="RGBA", width=256, show_label=True, label="Input Image", ) example_folder = os.path.join(os.path.dirname(__file__), "./example_images") example_fns = [os.path.join(example_folder, example) for example in sorted(os.listdir(example_folder))] gr.Examples( examples=example_fns, inputs=[input_image], cache_examples=False, label='Feel free to use one of our provided examples!', examples_per_page=30 ) input_image.change( fn=clear_drag, outputs=[drags], ) with gr.Column(scale=1): drag_image = gr.Image( type="numpy", label="Image with Drags", interactive=False, width=256, image_mode="RGB", ) input_image.select( fn=get_point, inputs=[input_image, drags], outputs=[drag_image], ) with gr.Column(scale=1): processed_image = gr.Image( type='numpy', label="Processed Image", interactive=False, width=256, height=256, image_mode='RGB', ) processed_image_highres = gr.Image(type='pil', image_mode='RGB', visible=False) with gr.Accordion('Advanced preprocessing options', open=True): with gr.Row(): with gr.Column(): preprocess_chk_group = gr.CheckboxGroup( ['Preprocess with Segmentation'], label='Segment', info=PREPROCESS_INSTRUCTION ) preprocess_button = gr.Button( value="Preprocess Input Image", ) preprocess_button.click( fn=preprocess_image, inputs=[input_image, preprocess_chk_group, drags], outputs=[processed_image, drags], queue=True, ) with gr.Column(scale=1): generated_image = gr.Image( type="numpy", label="Generated Image", interactive=False, height=256, width=256, image_mode="RGB", ) with gr.Accordion('Advanced generation options', open=True): with gr.Row(): with gr.Column(): seed = gr.Slider(label="seed", value=0, minimum=0, maximum=10000, step=1, randomize=False) cfg_scale = gr.Slider( label="classifier-free guidance weight", value=5, minimum=1, maximum=10, step=0.1 ) generate_button = gr.Button( value="Generate Image", ) generate_button.click( fn=generate_image, inputs=[processed_image, seed, cfg_scale, drags], outputs=[generated_image], ) demo.launch()