import sys import os from pathlib import Path import gc # Add the StableCascade and CSD directories to the Python path app_dir = Path(__file__).parent sys.path.extend([ str(app_dir), str(app_dir / "third_party" / "StableCascade"), str(app_dir / "third_party" / "CSD") ]) import yaml import torch from tqdm import tqdm from accelerate.utils import set_module_tensor_to_device import torch.nn.functional as F import torchvision.transforms as T from lang_sam import LangSAM from inference.utils import * from core.utils import load_or_fail from train import WurstCoreC, WurstCoreB from gdf_rbm import RBM from stage_c_rbm import StageCRBM from utils import WurstCoreCRBM from gdf.schedulers import CosineSchedule from gdf import VPScaler, CosineTNoiseCond, DDPMSampler, P2LossWeight, AdaptiveLossWeight from gdf.targets import EpsilonTarget import PIL # Device configuration device = torch.device("cuda:0" if torch.cuda.is_available() else "cpu") print(device) # Flag for low VRAM usage low_vram = True # Function definition for low VRAM usage if low_vram: def models_to(model, device="cpu", excepts=None): """ Change the device of nn.Modules within a class, skipping specified attributes. """ for attr_name in dir(model): if attr_name.startswith('__') and attr_name.endswith('__'): continue # skip special attributes attr_value = getattr(model, attr_name, None) if isinstance(attr_value, torch.nn.Module): if excepts and attr_name in excepts: print(f"Except '{attr_name}'") continue print(f"Change device of '{attr_name}' to {device}") attr_value.to(device) torch.cuda.empty_cache() # Stage C model configuration config_file = 'third_party/StableCascade/configs/inference/stage_c_3b.yaml' with open(config_file, "r", encoding="utf-8") as file: loaded_config = yaml.safe_load(file) core = WurstCoreCRBM(config_dict=loaded_config, device=device, training=False) # Stage B model configuration config_file_b = 'third_party/StableCascade/configs/inference/stage_b_3b.yaml' with open(config_file_b, "r", encoding="utf-8") as file: config_file_b = yaml.safe_load(file) core_b = WurstCoreB(config_dict=config_file_b, device=device, training=False) # Setup extras and models for Stage C extras = core.setup_extras_pre() gdf_rbm = RBM( schedule=CosineSchedule(clamp_range=[0.0001, 0.9999]), input_scaler=VPScaler(), target=EpsilonTarget(), noise_cond=CosineTNoiseCond(), loss_weight=AdaptiveLossWeight(), ) sampling_configs = { "cfg": 5, "sampler": DDPMSampler(gdf_rbm), "shift": 1, "timesteps": 20 } extras = core.Extras( gdf=gdf_rbm, sampling_configs=sampling_configs, transforms=extras.transforms, effnet_preprocess=extras.effnet_preprocess, clip_preprocess=extras.clip_preprocess ) models = core.setup_models(extras) models.generator.eval().requires_grad_(False) # Setup extras and models for Stage B extras_b = core_b.setup_extras_pre() models_b = core_b.setup_models(extras_b, skip_clip=True) models_b = WurstCoreB.Models( **{**models_b.to_dict(), 'tokenizer': models.tokenizer, 'text_model': models.text_model} ) models_b.generator.bfloat16().eval().requires_grad_(False) # Off-load old generator (low VRAM mode) if low_vram: models.generator.to("cpu") torch.cuda.empty_cache() # Load and configure new generator generator_rbm = StageCRBM() for param_name, param in load_or_fail(core.config.generator_checkpoint_path).items(): set_module_tensor_to_device(generator_rbm, param_name, "cpu", value=param) generator_rbm = generator_rbm.to(getattr(torch, core.config.dtype)).to(device) generator_rbm = core.load_model(generator_rbm, 'generator') # Create models_rbm instance models_rbm = core.Models( effnet=models.effnet, previewer=models.previewer, generator=generator_rbm, generator_ema=models.generator_ema, tokenizer=models.tokenizer, text_model=models.text_model, image_model=models.image_model ) models_rbm.generator.eval().requires_grad_(False) def reset_inference_state(): global models_rbm, models_b, extras, extras_b, device, core, core_b # Reset sampling configurations extras.sampling_configs['cfg'] = 5 extras.sampling_configs['shift'] = 1 extras.sampling_configs['timesteps'] = 20 extras.sampling_configs['t_start'] = 1.0 extras_b.sampling_configs['cfg'] = 1.1 extras_b.sampling_configs['shift'] = 1 extras_b.sampling_configs['timesteps'] = 10 extras_b.sampling_configs['t_start'] = 1.0 # Reset models models_rbm = core.setup_models(extras) models_b = core_b.setup_models(extras_b, skip_clip=True) models_b = WurstCoreB.Models( **{**models_b.to_dict(), 'tokenizer': models_rbm.tokenizer, 'text_model': models_rbm.text_model} ) # Move models to the correct device if low_vram: models_to(models_rbm, device="cpu", excepts=["generator", "previewer"]) models_b.generator.to("cpu") else: models_to(models_rbm, device=device) models_b.generator.to(device) # Ensure effnet is on the correct device models_rbm.effnet.to(device) # Set models to eval mode and disable gradients models_rbm.generator.eval().requires_grad_(False) models_b.generator.bfloat16().eval().requires_grad_(False) # Clear CUDA cache torch.cuda.empty_cache() gc.collect() def infer(style_description, ref_style_file, caption): global models_rbm, models_b try: height=1024 width=1024 batch_size=1 output_file='output.png' stage_c_latent_shape, stage_b_latent_shape = calculate_latent_sizes(height, width, batch_size=batch_size) extras.sampling_configs['cfg'] = 4 extras.sampling_configs['shift'] = 2 extras.sampling_configs['timesteps'] = 20 extras.sampling_configs['t_start'] = 1.0 extras_b.sampling_configs['cfg'] = 1.1 extras_b.sampling_configs['shift'] = 1 extras_b.sampling_configs['timesteps'] = 10 extras_b.sampling_configs['t_start'] = 1.0 ref_style = resize_image(PIL.Image.open(ref_style_file).convert("RGB")).unsqueeze(0).expand(batch_size, -1, -1, -1).to(device) batch = {'captions': [caption] * batch_size} batch['style'] = ref_style # Ensure effnet is on the correct device models_rbm.effnet.to(device) x0_style_forward = models_rbm.effnet(extras.effnet_preprocess(ref_style)) conditions = core.get_conditions(batch, models_rbm, extras, is_eval=True, is_unconditional=False, eval_image_embeds=True, eval_style=True, eval_csd=False) unconditions = core.get_conditions(batch, models_rbm, extras, is_eval=True, is_unconditional=True, eval_image_embeds=False) conditions_b = core_b.get_conditions(batch, models_b, extras_b, is_eval=True, is_unconditional=False) unconditions_b = core_b.get_conditions(batch, models_b, extras_b, is_eval=True, is_unconditional=True) if low_vram: # The sampling process uses more vram, so we offload everything except two modules to the cpu. models_to(models_rbm, device="cpu", excepts=["generator", "previewer"]) # Stage C reverse process. sampling_c = extras.gdf.sample( models_rbm.generator, conditions, stage_c_latent_shape, unconditions, device=device, **extras.sampling_configs, x0_style_forward=x0_style_forward, apply_pushforward=False, tau_pushforward=8, num_iter=3, eta=0.1, tau=20, eval_csd=True, extras=extras, models=models_rbm, lam_style=1, lam_txt_alignment=1.0, use_ddim_sampler=True, ) for (sampled_c, _, _) in tqdm(sampling_c, total=extras.sampling_configs['timesteps']): sampled_c = sampled_c # Stage B reverse process. with torch.no_grad(), torch.cuda.amp.autocast(dtype=torch.bfloat16): conditions_b['effnet'] = sampled_c unconditions_b['effnet'] = torch.zeros_like(sampled_c) sampling_b = extras_b.gdf.sample( models_b.generator, conditions_b, stage_b_latent_shape, unconditions_b, device=device, **extras_b.sampling_configs, ) for (sampled_b, _, _) in tqdm(sampling_b, total=extras_b.sampling_configs['timesteps']): sampled_b = sampled_b sampled = models_b.stage_a.decode(sampled_b).float() sampled = torch.cat([ torch.nn.functional.interpolate(ref_style.cpu(), size=(height, width)), sampled.cpu(), ], dim=0) # Remove the batch dimension and keep only the generated image sampled = sampled[1] # This selects the generated image, discarding the reference style image # Ensure the tensor is in [C, H, W] format if sampled.dim() == 3 and sampled.shape[0] == 3: sampled_image = T.ToPILImage()(sampled) # Convert tensor to PIL image sampled_image.save(output_file) # Save the image as a PNG else: raise ValueError(f"Expected tensor of shape [3, H, W] but got {sampled.shape}") return output_file # Return the path to the saved image finally: # Reset the state after inference, regardless of success or failure reset_inference_state() import gradio as gr gr.Interface( fn = infer, inputs=[gr.Textbox(label="style description"), gr.Image(label="Ref Style File", type="filepath"), gr.Textbox(label="caption")], outputs=[gr.Image()] ).launch()