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from functools import partial | |
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 | |
TITLE = '''DragAPart: Learning a Part-Level Motion Prior for Articulated Objects''' | |
DESCRIPTION = """ | |
<div> | |
Try <a href='https://arxiv.org/abs/24xx.xxxxx'><b>DragAPart</b></a> yourself to manipulate your favorite articulated objects in 2 seconds! | |
</div> | |
""" | |
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"]) | |
model = model.to("cuda") | |
return model | |
def sam_segment(predictor, input_image, drags, foreground_points=None): | |
image = np.asarray(input_image) | |
predictor.set_image(image) | |
with torch.no_grad(): | |
masks_bbox, _, _ = 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(SAM_predictor, 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( | |
SAM_predictor, | |
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( | |
model, | |
diffusion, | |
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) | |
x_cond = torch.cat([x_cond, x_cond], dim=0) | |
x_cond_clip = torch.cat([x_cond_clip, x_cond_clip], dim=0) | |
x_cond_extra = torch.cat([x_cond_extra, x_cond_extra], dim=0) | |
drags = torch.cat([drags, drags], dim=0) | |
hidden_cls = torch.cat([hidden_cls, hidden_cls], dim=0) | |
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) | |
return samples | |
def generate_image(model, image_processor, vae, clip_model, clip_vit, diffusion, 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 | |
samples = single_image_sample( | |
model, | |
diffusion, | |
x_cond, | |
cond_clip_features, | |
rel, | |
cfg_scale, | |
x_cond_extra, | |
drags, | |
cls_embedding, | |
num_steps=50, | |
) | |
with torch.no_grad(): | |
images = vae.decode(samples / 0.18215).sample | |
images = ((images + 1)[0].permute(1, 2, 0) * 127.5).cpu().numpy().clip(0, 255).astype(np.uint8) | |
return images | |
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, | |
) | |
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=partial(preprocess_image, sam_predictor), | |
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=partial(generate_image, model, image_processor, vae, clip_model, clip_vit, diffusion), | |
inputs=[processed_image, seed, cfg_scale, drags], | |
outputs=[generated_image], | |
) | |
demo.launch(share=True) | |