import gradio as gr import spaces import torch import torch.nn.functional as F from safetensors.numpy import save_file, load_file from omegaconf import OmegaConf from transformers import AutoConfig import cv2 from PIL import Image import numpy as np import json import os # from diffusers import StableDiffusionPipeline, StableDiffusionImg2ImgPipeline, StableDiffusionInpaintPipelineLegacy, StableDiffusionInpaintPipeline, DDIMScheduler, AutoencoderKL from diffusers import AutoencoderKL, DDPMScheduler, UNet2DConditionModel, DDIMScheduler from diffusers import DDIMScheduler, DDPMScheduler, DPMSolverMultistepScheduler from diffusers.image_processor import VaeImageProcessor # from models.pipeline_mimicbrush import MimicBrushPipeline from models.ReferenceNet import ReferenceNet from models.depth_guider import DepthGuider from mimicbrush import MimicBrush_RefNet from data_utils import * from modelscope.hub.snapshot_download import snapshot_download as ms_snapshot_download from huggingface_hub import snapshot_download snapshot_download(repo_id="xichenhku/cleansd", local_dir="./cleansd") print('=== Pretrained SD weights downloaded ===') snapshot_download(repo_id="xichenhku/MimicBrush", local_dir="./MimicBrush") print('=== MimicBrush weights downloaded ===') #sd_dir = ms_snapshot_download('xichen/cleansd', cache_dir='./modelscope') #print('=== Pretrained SD weights downloaded ===') #model_dir = ms_snapshot_download('xichen/MimicBrush', cache_dir='./modelscope') #print('=== MimicBrush weights downloaded ===') val_configs = OmegaConf.load('./configs/inference.yaml') # === import Depth Anything === import sys sys.path.append("./depthanything") from torchvision.transforms import Compose from depthanything.fast_import import depth_anything_model from depthanything.depth_anything.util.transform import Resize, NormalizeImage, PrepareForNet transform = Compose([ Resize( width=518, height=518, resize_target=False, keep_aspect_ratio=True, ensure_multiple_of=14, resize_method='lower_bound', image_interpolation_method=cv2.INTER_CUBIC, ), NormalizeImage(mean=[0.485, 0.456, 0.406], std=[0.229, 0.224, 0.225]), PrepareForNet(), ]) depth_anything_model.load_state_dict(torch.load(val_configs.model_path.depth_model)) # === load the checkpoint === base_model_path = val_configs.model_path.pretrained_imitativer_path vae_model_path = val_configs.model_path.pretrained_vae_name_or_path image_encoder_path = val_configs.model_path.image_encoder_path ref_model_path = val_configs.model_path.pretrained_reference_path mimicbrush_ckpt = val_configs.model_path.mimicbrush_ckpt_path device = "cuda" def pad_img_to_square(original_image, is_mask=False): width, height = original_image.size if height == width: return original_image if height > width: padding = (height - width) // 2 new_size = (height, height) else: padding = (width - height) // 2 new_size = (width, width) if is_mask: new_image = Image.new("RGB", new_size, "black") else: new_image = Image.new("RGB", new_size, "white") if height > width: new_image.paste(original_image, (padding, 0)) else: new_image.paste(original_image, (0, padding)) return new_image def collage_region(low, high, mask): mask = (np.array(mask) > 128).astype(np.uint8) low = np.array(low).astype(np.uint8) low = (low * 0).astype(np.uint8) high = np.array(high).astype(np.uint8) mask_3 = mask collage = low * mask_3 + high * (1-mask_3) collage = Image.fromarray(collage) return collage def resize_image_keep_aspect_ratio(image, target_size = 512): height, width = image.shape[:2] if height > width: new_height = target_size new_width = int(width * (target_size / height)) else: new_width = target_size new_height = int(height * (target_size / width)) resized_image = cv2.resize(image, (new_width, new_height)) return resized_image def crop_padding_and_resize(ori_image, square_image): ori_height, ori_width, _ = ori_image.shape scale = max(ori_height / square_image.shape[0], ori_width / square_image.shape[1]) resized_square_image = cv2.resize(square_image, (int(square_image.shape[1] * scale), int(square_image.shape[0] * scale))) padding_size = max(resized_square_image.shape[0] - ori_height, resized_square_image.shape[1] - ori_width) if ori_height < ori_width: top = padding_size // 2 bottom = resized_square_image.shape[0] - (padding_size - top) cropped_image = resized_square_image[top:bottom, :,:] else: left = padding_size // 2 right = resized_square_image.shape[1] - (padding_size - left) cropped_image = resized_square_image[:, left:right,:] return cropped_image def vis_mask(image, mask): # mask 3 channle 255 mask = mask[:,:,0] mask_contours, _ = cv2.findContours(mask, cv2.RETR_EXTERNAL, cv2.CHAIN_APPROX_SIMPLE) # Draw outlines, using random colors outline_opacity = 0.5 outline_thickness = 5 outline_color = np.concatenate([ [255,255,255], [outline_opacity] ]) white_mask = np.ones_like(image) * 255 mask_bin_3 = np.stack([mask,mask,mask],-1) > 128 alpha = 0.5 image = ( white_mask * alpha + image * (1-alpha) ) * mask_bin_3 + image * (1-mask_bin_3) cv2.polylines(image, mask_contours, True, outline_color, outline_thickness, cv2.LINE_AA) return image noise_scheduler = DDIMScheduler( num_train_timesteps=1000, beta_start=0.00085, beta_end=0.012, beta_schedule="scaled_linear", clip_sample=False, set_alpha_to_one=False, steps_offset=1, ) vae = AutoencoderKL.from_pretrained(vae_model_path).to(dtype=torch.float16) unet = UNet2DConditionModel.from_pretrained(base_model_path, subfolder="unet", in_channels=13, low_cpu_mem_usage=False, ignore_mismatched_sizes=True).to(dtype=torch.float16) pipe = MimicBrushPipeline.from_pretrained( base_model_path, torch_dtype=torch.float16, scheduler=noise_scheduler, vae=vae, unet=unet, feature_extractor=None, safety_checker=None, ) depth_guider = DepthGuider() referencenet = ReferenceNet.from_pretrained(ref_model_path, subfolder="unet").to(dtype=torch.float16) mimicbrush_model = MimicBrush_RefNet(pipe, image_encoder_path, mimicbrush_ckpt, depth_anything_model, depth_guider, referencenet, device) mask_processor = VaeImageProcessor(vae_scale_factor=1, do_normalize=False, do_binarize=True, do_convert_grayscale=True) @spaces.GPU def infer_single(ref_image, target_image, target_mask, seed = -1, num_inference_steps=50, guidance_scale = 5, enable_shape_control = False): #return ref_image """ mask: 0/1 1-channel np.array image: rgb np.array """ ref_image = ref_image.astype(np.uint8) target_image = target_image.astype(np.uint8) target_mask = target_mask .astype(np.uint8) ref_image = Image.fromarray(ref_image.astype(np.uint8)) ref_image = pad_img_to_square(ref_image) target_image = pad_img_to_square(Image.fromarray(target_image)) target_image_low = target_image target_mask = np.stack([target_mask,target_mask,target_mask],-1).astype(np.uint8) * 255 target_mask_np = target_mask.copy() target_mask = Image.fromarray(target_mask) target_mask = pad_img_to_square(target_mask, True) target_image_ori = target_image.copy() target_image = collage_region(target_image_low, target_image, target_mask) depth_image = target_image_ori.copy() depth_image = np.array(depth_image) depth_image = transform({'image': depth_image})['image'] depth_image = torch.from_numpy(depth_image).unsqueeze(0) / 255 if not enable_shape_control: depth_image = depth_image * 0 mask_pt = mask_processor.preprocess(target_mask, height=512, width=512) pred, depth_pred = mimicbrush_model.generate(pil_image=ref_image, depth_image = depth_image, num_samples=1, num_inference_steps=num_inference_steps, seed=seed, image=target_image, mask_image=mask_pt, strength=1.0, guidance_scale=guidance_scale) depth_pred = F.interpolate(depth_pred, size=(512,512), mode = 'bilinear', align_corners=True)[0][0] depth_pred = (depth_pred - depth_pred.min()) / (depth_pred.max() - depth_pred.min()) * 255.0 depth_pred = depth_pred.detach().cpu().numpy().astype(np.uint8) depth_pred = cv2.applyColorMap(depth_pred, cv2.COLORMAP_INFERNO)[:,:,::-1] pred = pred[0] pred = np.array(pred).astype(np.uint8) return pred, depth_pred.astype(np.uint8) def inference_single_image(ref_image, tar_image, tar_mask, ddim_steps, scale, seed, enable_shape_control, ): if seed == -1: seed = np.random.randint(10000) pred, depth_pred = infer_single(ref_image, tar_image, tar_mask, seed, num_inference_steps=ddim_steps, guidance_scale = scale, enable_shape_control = enable_shape_control) return pred, depth_pred def run_local(base, ref, *args): # print("base文件:",base) # print("base文件背景图:", base["background"]) # print("base文件层次图:", base["layers"]) # print("参考图:", ref) image = base["background"].convert("RGB") #base["image"].convert("RGB") mask = base["layers"][0] #base["mask"].convert("L") image = np.asarray(image) mask = np.asarray(mask)[:,:,-1] #print(image.shape, mask.shape, mask.max(), mask.min()) mask = np.where(mask > 128, 1, 0).astype(np.uint8) ref_image = ref.convert("RGB") ref_image = np.asarray(ref_image) if mask.sum() == 0: raise gr.Error('No mask for the background image.') mask_3 = np.stack([mask,mask,mask],-1).astype(np.uint8) * 255 mask_alpha = mask_3.copy() for i in range(10): mask_alpha = cv2.GaussianBlur(mask_alpha, (3, 3), 0) synthesis, depth_pred = inference_single_image(ref_image.copy(), image.copy(), mask.copy(), *args) synthesis = crop_padding_and_resize(image, synthesis) depth_pred = crop_padding_and_resize(image, depth_pred) mask_3_bin = mask_alpha / 255 synthesis = synthesis * mask_3_bin + image * (1-mask_3_bin) vis_source = vis_mask(image, mask_3).astype(np.uint8) return [synthesis.astype(np.uint8), depth_pred.astype(np.uint8), vis_source, mask_3] with gr.Blocks() as demo: with gr.Column(): gr.Markdown("# MimicBrush: Zero-shot Image Editing with Reference Imitation ") with gr.Row(): baseline_gallery = gr.Gallery(label='Output', show_label=True, elem_id="gallery", columns=1, height=768) with gr.Accordion("Advanced Option", open=True): num_samples = 1 ddim_steps = gr.Slider(label="Steps", minimum=1, maximum=100, value=50, step=1) scale = gr.Slider(label="Guidance Scale", minimum=-30.0, maximum=30.0, value=5.0, step=0.1) seed = gr.Slider(label="Seed", minimum=-1, maximum=999999999, step=1, value=-1) enable_shape_control = gr.Checkbox(label='Keep the original shape', value=False, interactive = True) gr.Markdown("### Tutorial") gr.Markdown("1. Upload the source image and the reference image") gr.Markdown("2. Select the \"draw button\" to mask the to-edit region on the source image ") gr.Markdown("3. Click generate ") gr.Markdown("#### You shoud click \"keep the original shape\" to conduct texture transfer ") gr.Markdown("# Upload the source image and reference image") gr.Markdown("### Tips: you could adjust the brush size") with gr.Row(): base = gr.ImageEditor( label="Source", type="pil", brush=gr.Brush(colors=["#FFFFFF"],default_size = 30,color_mode = "fixed"), layers = False, interactive=True ) ref = gr.Image(label="Reference", sources="upload", type="pil", height=512) run_local_button = gr.Button(value="Run") with gr.Row(): gr.Examples( examples=[ [ './demo_example/005_source.png', './demo_example/005_reference.png', 0 ], [ './demo_example/004_source.png', './demo_example/004_reference.png', 0 ], [ './demo_example/000_source.png', './demo_example/000_reference.png', 0 ], [ './demo_example/003_source.png', './demo_example/003_reference.png', 0 ], [ './demo_example/006_source.png', './demo_example/006_reference.png', 0 ], [ './demo_example/001_source.png', './demo_example/001_reference.png', 1 ], [ './demo_example/002_source.png', './demo_example/002_reference.png', 1 ], [ './demo_example/007_source.png', './demo_example/007_reference.png', 1 ], ], inputs=[ base, ref, enable_shape_control ], cache_examples=False, examples_per_page=100) run_local_button.click(fn=run_local, inputs=[base, ref, ddim_steps, scale, seed, enable_shape_control ], outputs=[baseline_gallery] ) demo.launch(server_name="0.0.0.0")