# Copyright 2024-2025 The Alibaba Wan Team Authors. All rights reserved. import argparse import binascii import os import os.path as osp import torchvision.transforms.functional as TF import torch.nn.functional as F import imageio import torch import decord import torchvision from PIL import Image import numpy as np from rembg import remove, new_session import random __all__ = ['cache_video', 'cache_image', 'str2bool'] from PIL import Image def seed_everything(seed: int): random.seed(seed) np.random.seed(seed) torch.manual_seed(seed) if torch.cuda.is_available(): torch.cuda.manual_seed(seed) if torch.backends.mps.is_available(): torch.mps.manual_seed(seed) def resample(video_fps, video_frames_count, max_target_frames_count, target_fps, start_target_frame ): import math if video_fps < target_fps : video_fps = target_fps video_frame_duration = 1 /video_fps target_frame_duration = 1 / target_fps target_time = start_target_frame * target_frame_duration frame_no = math.ceil(target_time / video_frame_duration) cur_time = frame_no * video_frame_duration frame_ids =[] while True: if max_target_frames_count != 0 and len(frame_ids) >= max_target_frames_count : break diff = round( (target_time -cur_time) / video_frame_duration , 5) add_frames_count = math.ceil( diff) frame_no += add_frames_count if frame_no >= video_frames_count: break frame_ids.append(frame_no) cur_time += add_frames_count * video_frame_duration target_time += target_frame_duration frame_ids = frame_ids[:max_target_frames_count] return frame_ids def get_video_frame(file_name, frame_no): decord.bridge.set_bridge('torch') reader = decord.VideoReader(file_name) frame = reader.get_batch([frame_no]).squeeze(0) img = Image.fromarray(frame.numpy().astype(np.uint8)) return img def resize_lanczos(img, h, w): img = Image.fromarray(np.clip(255. * img.movedim(0, -1).cpu().numpy(), 0, 255).astype(np.uint8)) img = img.resize((w,h), resample=Image.Resampling.LANCZOS) return torch.from_numpy(np.array(img).astype(np.float32) / 255.0).movedim(-1, 0) def remove_background(img, session=None): if session ==None: session = new_session() img = Image.fromarray(np.clip(255. * img.movedim(0, -1).cpu().numpy(), 0, 255).astype(np.uint8)) img = remove(img, session=session, alpha_matting = True, bgcolor=[255, 255, 255, 0]).convert('RGB') return torch.from_numpy(np.array(img).astype(np.float32) / 255.0).movedim(-1, 0) def convert_tensor_to_image(t, frame_no = -1): t = t[:, frame_no] if frame_no >= 0 else t return Image.fromarray(t.clone().add_(1.).mul_(127.5).permute(1,2,0).to(torch.uint8).cpu().numpy()) def save_image(tensor_image, name, frame_no = -1): convert_tensor_to_image(tensor_image, frame_no).save(name) def get_outpainting_full_area_dimensions(frame_height,frame_width, outpainting_dims): outpainting_top, outpainting_bottom, outpainting_left, outpainting_right= outpainting_dims frame_height = int(frame_height * (100 + outpainting_top + outpainting_bottom) / 100) frame_width = int(frame_width * (100 + outpainting_left + outpainting_right) / 100) return frame_height, frame_width def get_outpainting_frame_location(final_height, final_width, outpainting_dims, block_size = 8): outpainting_top, outpainting_bottom, outpainting_left, outpainting_right= outpainting_dims raw_height = int(final_height / ((100 + outpainting_top + outpainting_bottom) / 100)) height = int(raw_height / block_size) * block_size extra_height = raw_height - height raw_width = int(final_width / ((100 + outpainting_left + outpainting_right) / 100)) width = int(raw_width / block_size) * block_size extra_width = raw_width - width margin_top = int(outpainting_top/(100 + outpainting_top + outpainting_bottom) * final_height) if extra_height != 0 and (outpainting_top + outpainting_bottom) != 0: margin_top += int(outpainting_top / (outpainting_top + outpainting_bottom) * extra_height) if (margin_top + height) > final_height or outpainting_bottom == 0: margin_top = final_height - height margin_left = int(outpainting_left/(100 + outpainting_left + outpainting_right) * final_width) if extra_width != 0 and (outpainting_left + outpainting_right) != 0: margin_left += int(outpainting_left / (outpainting_left + outpainting_right) * extra_height) if (margin_left + width) > final_width or outpainting_right == 0: margin_left = final_width - width return height, width, margin_top, margin_left def calculate_new_dimensions(canvas_height, canvas_width, height, width, fit_into_canvas, block_size = 16): if fit_into_canvas == None: return height, width if fit_into_canvas: scale1 = min(canvas_height / height, canvas_width / width) scale2 = min(canvas_width / height, canvas_height / width) scale = max(scale1, scale2) else: scale = (canvas_height * canvas_width / (height * width))**(1/2) new_height = round( height * scale / block_size) * block_size new_width = round( width * scale / block_size) * block_size return new_height, new_width def resize_and_remove_background(img_list, budget_width, budget_height, rm_background, fit_into_canvas = False ): if rm_background > 0: session = new_session() output_list =[] for i, img in enumerate(img_list): width, height = img.size if fit_into_canvas: white_canvas = np.ones((budget_height, budget_width, 3), dtype=np.uint8) * 255 scale = min(budget_height / height, budget_width / width) new_height = int(height * scale) new_width = int(width * scale) resized_image= img.resize((new_width,new_height), resample=Image.Resampling.LANCZOS) top = (budget_height - new_height) // 2 left = (budget_width - new_width) // 2 white_canvas[top:top + new_height, left:left + new_width] = np.array(resized_image) resized_image = Image.fromarray(white_canvas) else: scale = (budget_height * budget_width / (height * width))**(1/2) new_height = int( round(height * scale / 16) * 16) new_width = int( round(width * scale / 16) * 16) resized_image= img.resize((new_width,new_height), resample=Image.Resampling.LANCZOS) if rm_background == 1 or rm_background == 2 and i > 0 : # resized_image = remove(resized_image, session=session, alpha_matting_erode_size = 1,alpha_matting_background_threshold = 70, alpha_foreground_background_threshold = 100, alpha_matting = True, bgcolor=[255, 255, 255, 0]).convert('RGB') resized_image = remove(resized_image, session=session, alpha_matting_erode_size = 1, alpha_matting = True, bgcolor=[255, 255, 255, 0]).convert('RGB') output_list.append(resized_image) #alpha_matting_background_threshold = 30, alpha_foreground_background_threshold = 200, return output_list def rand_name(length=8, suffix=''): name = binascii.b2a_hex(os.urandom(length)).decode('utf-8') if suffix: if not suffix.startswith('.'): suffix = '.' + suffix name += suffix return name def cache_video(tensor, save_file=None, fps=30, suffix='.mp4', nrow=8, normalize=True, value_range=(-1, 1), retry=5): # cache file cache_file = osp.join('/tmp', rand_name( suffix=suffix)) if save_file is None else save_file # save to cache error = None for _ in range(retry): try: # preprocess tensor = tensor.clamp(min(value_range), max(value_range)) tensor = torch.stack([ torchvision.utils.make_grid( u, nrow=nrow, normalize=normalize, value_range=value_range) for u in tensor.unbind(2) ], dim=1).permute(1, 2, 3, 0) tensor = (tensor * 255).type(torch.uint8).cpu() # write video writer = imageio.get_writer( cache_file, fps=fps, codec='libx264', quality=8) for frame in tensor.numpy(): writer.append_data(frame) writer.close() return cache_file except Exception as e: error = e continue else: print(f'cache_video failed, error: {error}', flush=True) return None def cache_image(tensor, save_file, nrow=8, normalize=True, value_range=(-1, 1), retry=5): # cache file suffix = osp.splitext(save_file)[1] if suffix.lower() not in [ '.jpg', '.jpeg', '.png', '.tiff', '.gif', '.webp' ]: suffix = '.png' # save to cache error = None for _ in range(retry): try: tensor = tensor.clamp(min(value_range), max(value_range)) torchvision.utils.save_image( tensor, save_file, nrow=nrow, normalize=normalize, value_range=value_range) return save_file except Exception as e: error = e continue def str2bool(v): """ Convert a string to a boolean. Supported true values: 'yes', 'true', 't', 'y', '1' Supported false values: 'no', 'false', 'f', 'n', '0' Args: v (str): String to convert. Returns: bool: Converted boolean value. Raises: argparse.ArgumentTypeError: If the value cannot be converted to boolean. """ if isinstance(v, bool): return v v_lower = v.lower() if v_lower in ('yes', 'true', 't', 'y', '1'): return True elif v_lower in ('no', 'false', 'f', 'n', '0'): return False else: raise argparse.ArgumentTypeError('Boolean value expected (True/False)') import sys, time # Global variables to track download progress _start_time = None _last_time = None _last_downloaded = 0 _speed_history = [] _update_interval = 0.5 # Update speed every 0.5 seconds def progress_hook(block_num, block_size, total_size, filename=None): """ Simple progress bar hook for urlretrieve Args: block_num: Number of blocks downloaded so far block_size: Size of each block in bytes total_size: Total size of the file in bytes filename: Name of the file being downloaded (optional) """ global _start_time, _last_time, _last_downloaded, _speed_history, _update_interval current_time = time.time() downloaded = block_num * block_size # Initialize timing on first call if _start_time is None or block_num == 0: _start_time = current_time _last_time = current_time _last_downloaded = 0 _speed_history = [] # Calculate download speed only at specified intervals speed = 0 if current_time - _last_time >= _update_interval: if _last_time > 0: current_speed = (downloaded - _last_downloaded) / (current_time - _last_time) _speed_history.append(current_speed) # Keep only last 5 speed measurements for smoothing if len(_speed_history) > 5: _speed_history.pop(0) # Average the recent speeds for smoother display speed = sum(_speed_history) / len(_speed_history) _last_time = current_time _last_downloaded = downloaded elif _speed_history: # Use the last calculated average speed speed = sum(_speed_history) / len(_speed_history) # Format file sizes and speed def format_bytes(bytes_val): for unit in ['B', 'KB', 'MB', 'GB']: if bytes_val < 1024: return f"{bytes_val:.1f}{unit}" bytes_val /= 1024 return f"{bytes_val:.1f}TB" file_display = filename if filename else "Unknown file" if total_size <= 0: # If total size is unknown, show downloaded bytes speed_str = f" @ {format_bytes(speed)}/s" if speed > 0 else "" line = f"\r{file_display}: {format_bytes(downloaded)}{speed_str}" # Clear any trailing characters by padding with spaces sys.stdout.write(line.ljust(80)) sys.stdout.flush() return downloaded = block_num * block_size percent = min(100, (downloaded / total_size) * 100) # Create progress bar (40 characters wide to leave room for other info) bar_length = 40 filled = int(bar_length * percent / 100) bar = '█' * filled + '░' * (bar_length - filled) # Format file sizes and speed def format_bytes(bytes_val): for unit in ['B', 'KB', 'MB', 'GB']: if bytes_val < 1024: return f"{bytes_val:.1f}{unit}" bytes_val /= 1024 return f"{bytes_val:.1f}TB" speed_str = f" @ {format_bytes(speed)}/s" if speed > 0 else "" # Display progress with filename first line = f"\r{file_display}: [{bar}] {percent:.1f}% ({format_bytes(downloaded)}/{format_bytes(total_size)}){speed_str}" # Clear any trailing characters by padding with spaces sys.stdout.write(line.ljust(100)) sys.stdout.flush() # Print newline when complete if percent >= 100: print() # Wrapper function to include filename in progress hook def create_progress_hook(filename): """Creates a progress hook with the filename included""" global _start_time, _last_time, _last_downloaded, _speed_history # Reset timing variables for new download _start_time = None _last_time = None _last_downloaded = 0 _speed_history = [] def hook(block_num, block_size, total_size): return progress_hook(block_num, block_size, total_size, filename) return hook