620 lines
24 KiB
Python
620 lines
24 KiB
Python
# Copyright 2024-2025 The Alibaba Wan Team Authors. All rights reserved.
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import gc
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import logging
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import math
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import os
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import random
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import sys
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import types
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from contextlib import contextmanager
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from functools import partial
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import torch
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import torch.cuda.amp as amp
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import torch.distributed as dist
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import torchvision.transforms.functional as TF
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from PIL import Image
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from tqdm import tqdm
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from .distributed.fsdp import shard_model
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from .distributed.sequence_parallel import sp_attn_forward, sp_dit_forward
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from .distributed.util import get_world_size
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from .modules.model import WanModel
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from .modules.t5 import T5EncoderModel
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from .modules.vae2_2 import Wan2_2_VAE
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from .utils.fm_solvers import (
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FlowDPMSolverMultistepScheduler,
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get_sampling_sigmas,
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retrieve_timesteps,
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)
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from .utils.fm_solvers_unipc import FlowUniPCMultistepScheduler
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from .utils.utils import best_output_size, masks_like
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class WanTI2V:
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def __init__(
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self,
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config,
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checkpoint_dir,
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device_id=0,
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rank=0,
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t5_fsdp=False,
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dit_fsdp=False,
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use_sp=False,
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t5_cpu=False,
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init_on_cpu=True,
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convert_model_dtype=False,
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):
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r"""
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Initializes the Wan text-to-video generation model components.
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Args:
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config (EasyDict):
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Object containing model parameters initialized from config.py
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checkpoint_dir (`str`):
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Path to directory containing model checkpoints
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device_id (`int`, *optional*, defaults to 0):
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Id of target GPU device
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rank (`int`, *optional*, defaults to 0):
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Process rank for distributed training
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t5_fsdp (`bool`, *optional*, defaults to False):
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Enable FSDP sharding for T5 model
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dit_fsdp (`bool`, *optional*, defaults to False):
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Enable FSDP sharding for DiT model
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use_sp (`bool`, *optional*, defaults to False):
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Enable distribution strategy of sequence parallel.
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t5_cpu (`bool`, *optional*, defaults to False):
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Whether to place T5 model on CPU. Only works without t5_fsdp.
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init_on_cpu (`bool`, *optional*, defaults to True):
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Enable initializing Transformer Model on CPU. Only works without FSDP or USP.
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convert_model_dtype (`bool`, *optional*, defaults to False):
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Convert DiT model parameters dtype to 'config.param_dtype'.
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Only works without FSDP.
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"""
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self.device = torch.device(f"cuda:{device_id}")
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self.config = config
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self.rank = rank
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self.t5_cpu = t5_cpu
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self.init_on_cpu = init_on_cpu
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self.num_train_timesteps = config.num_train_timesteps
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self.param_dtype = config.param_dtype
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if t5_fsdp or dit_fsdp or use_sp:
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self.init_on_cpu = False
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shard_fn = partial(shard_model, device_id=device_id)
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self.text_encoder = T5EncoderModel(
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text_len=config.text_len,
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dtype=config.t5_dtype,
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device=torch.device('cpu'),
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checkpoint_path=os.path.join(checkpoint_dir, config.t5_checkpoint),
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tokenizer_path=os.path.join(checkpoint_dir, config.t5_tokenizer),
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shard_fn=shard_fn if t5_fsdp else None)
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self.vae_stride = config.vae_stride
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self.patch_size = config.patch_size
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self.vae = Wan2_2_VAE(
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vae_pth=os.path.join(checkpoint_dir, config.vae_checkpoint),
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device=self.device)
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logging.info(f"Creating WanModel from {checkpoint_dir}")
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self.model = WanModel.from_pretrained(checkpoint_dir)
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self.model = self._configure_model(
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model=self.model,
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use_sp=use_sp,
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dit_fsdp=dit_fsdp,
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shard_fn=shard_fn,
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convert_model_dtype=convert_model_dtype)
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if use_sp:
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self.sp_size = get_world_size()
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else:
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self.sp_size = 1
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self.sample_neg_prompt = config.sample_neg_prompt
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def _configure_model(self, model, use_sp, dit_fsdp, shard_fn,
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convert_model_dtype):
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"""
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Configures a model object. This includes setting evaluation modes,
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applying distributed parallel strategy, and handling device placement.
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Args:
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model (torch.nn.Module):
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The model instance to configure.
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use_sp (`bool`):
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Enable distribution strategy of sequence parallel.
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dit_fsdp (`bool`):
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Enable FSDP sharding for DiT model.
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shard_fn (callable):
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The function to apply FSDP sharding.
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convert_model_dtype (`bool`):
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Convert DiT model parameters dtype to 'config.param_dtype'.
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Only works without FSDP.
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Returns:
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torch.nn.Module:
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The configured model.
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"""
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model.eval().requires_grad_(False)
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if use_sp:
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for block in model.blocks:
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block.self_attn.forward = types.MethodType(
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sp_attn_forward, block.self_attn)
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model.forward = types.MethodType(sp_dit_forward, model)
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if dist.is_initialized():
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dist.barrier()
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if dit_fsdp:
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model = shard_fn(model)
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else:
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if convert_model_dtype:
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model.to(self.param_dtype)
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if not self.init_on_cpu:
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model.to(self.device)
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return model
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def generate(self,
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input_prompt,
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img=None,
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size=(1280, 704),
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max_area=704 * 1280,
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frame_num=81,
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shift=5.0,
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sample_solver='unipc',
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sampling_steps=50,
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guide_scale=5.0,
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n_prompt="",
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seed=-1,
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offload_model=True):
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r"""
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Generates video frames from text prompt using diffusion process.
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Args:
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input_prompt (`str`):
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Text prompt for content generation
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img (PIL.Image.Image):
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Input image tensor. Shape: [3, H, W]
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size (`tuple[int]`, *optional*, defaults to (1280,704)):
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Controls video resolution, (width,height).
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max_area (`int`, *optional*, defaults to 704*1280):
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Maximum pixel area for latent space calculation. Controls video resolution scaling
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frame_num (`int`, *optional*, defaults to 81):
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How many frames to sample from a video. The number should be 4n+1
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shift (`float`, *optional*, defaults to 5.0):
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Noise schedule shift parameter. Affects temporal dynamics
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sample_solver (`str`, *optional*, defaults to 'unipc'):
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Solver used to sample the video.
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sampling_steps (`int`, *optional*, defaults to 50):
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Number of diffusion sampling steps. Higher values improve quality but slow generation
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guide_scale (`float`, *optional*, defaults 5.0):
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Classifier-free guidance scale. Controls prompt adherence vs. creativity.
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n_prompt (`str`, *optional*, defaults to ""):
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Negative prompt for content exclusion. If not given, use `config.sample_neg_prompt`
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seed (`int`, *optional*, defaults to -1):
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Random seed for noise generation. If -1, use random seed.
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offload_model (`bool`, *optional*, defaults to True):
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If True, offloads models to CPU during generation to save VRAM
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Returns:
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torch.Tensor:
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Generated video frames tensor. Dimensions: (C, N H, W) where:
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- C: Color channels (3 for RGB)
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- N: Number of frames (81)
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- H: Frame height (from size)
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- W: Frame width from size)
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"""
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# i2v
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if img is not None:
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return self.i2v(
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input_prompt=input_prompt,
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img=img,
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max_area=max_area,
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frame_num=frame_num,
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shift=shift,
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sample_solver=sample_solver,
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sampling_steps=sampling_steps,
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guide_scale=guide_scale,
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n_prompt=n_prompt,
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seed=seed,
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offload_model=offload_model)
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# t2v
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return self.t2v(
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input_prompt=input_prompt,
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size=size,
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frame_num=frame_num,
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shift=shift,
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sample_solver=sample_solver,
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sampling_steps=sampling_steps,
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guide_scale=guide_scale,
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n_prompt=n_prompt,
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seed=seed,
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offload_model=offload_model)
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def t2v(self,
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input_prompt,
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size=(1280, 704),
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frame_num=121,
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shift=5.0,
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sample_solver='unipc',
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sampling_steps=50,
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guide_scale=5.0,
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n_prompt="",
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seed=-1,
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offload_model=True):
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r"""
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Generates video frames from text prompt using diffusion process.
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Args:
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input_prompt (`str`):
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Text prompt for content generation
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size (`tuple[int]`, *optional*, defaults to (1280,704)):
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Controls video resolution, (width,height).
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frame_num (`int`, *optional*, defaults to 121):
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How many frames to sample from a video. The number should be 4n+1
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shift (`float`, *optional*, defaults to 5.0):
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Noise schedule shift parameter. Affects temporal dynamics
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sample_solver (`str`, *optional*, defaults to 'unipc'):
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Solver used to sample the video.
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sampling_steps (`int`, *optional*, defaults to 50):
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Number of diffusion sampling steps. Higher values improve quality but slow generation
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guide_scale (`float`, *optional*, defaults 5.0):
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Classifier-free guidance scale. Controls prompt adherence vs. creativity.
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n_prompt (`str`, *optional*, defaults to ""):
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Negative prompt for content exclusion. If not given, use `config.sample_neg_prompt`
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seed (`int`, *optional*, defaults to -1):
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Random seed for noise generation. If -1, use random seed.
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offload_model (`bool`, *optional*, defaults to True):
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If True, offloads models to CPU during generation to save VRAM
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Returns:
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torch.Tensor:
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Generated video frames tensor. Dimensions: (C, N H, W) where:
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- C: Color channels (3 for RGB)
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- N: Number of frames (81)
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- H: Frame height (from size)
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- W: Frame width from size)
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"""
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# preprocess
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F = frame_num
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target_shape = (self.vae.model.z_dim, (F - 1) // self.vae_stride[0] + 1,
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size[1] // self.vae_stride[1],
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size[0] // self.vae_stride[2])
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seq_len = math.ceil((target_shape[2] * target_shape[3]) /
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(self.patch_size[1] * self.patch_size[2]) *
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target_shape[1] / self.sp_size) * self.sp_size
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if n_prompt == "":
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n_prompt = self.sample_neg_prompt
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seed = seed if seed >= 0 else random.randint(0, sys.maxsize)
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seed_g = torch.Generator(device=self.device)
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seed_g.manual_seed(seed)
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if not self.t5_cpu:
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self.text_encoder.model.to(self.device)
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context = self.text_encoder([input_prompt], self.device)
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context_null = self.text_encoder([n_prompt], self.device)
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if offload_model:
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self.text_encoder.model.cpu()
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else:
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context = self.text_encoder([input_prompt], torch.device('cpu'))
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context_null = self.text_encoder([n_prompt], torch.device('cpu'))
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context = [t.to(self.device) for t in context]
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context_null = [t.to(self.device) for t in context_null]
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noise = [
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torch.randn(
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target_shape[0],
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target_shape[1],
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target_shape[2],
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target_shape[3],
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dtype=torch.float32,
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device=self.device,
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generator=seed_g)
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]
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@contextmanager
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def noop_no_sync():
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yield
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no_sync = getattr(self.model, 'no_sync', noop_no_sync)
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# evaluation mode
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with (
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torch.amp.autocast('cuda', dtype=self.param_dtype),
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torch.no_grad(),
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no_sync(),
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):
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if sample_solver == 'unipc':
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sample_scheduler = FlowUniPCMultistepScheduler(
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num_train_timesteps=self.num_train_timesteps,
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shift=1,
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use_dynamic_shifting=False)
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sample_scheduler.set_timesteps(
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sampling_steps, device=self.device, shift=shift)
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timesteps = sample_scheduler.timesteps
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elif sample_solver == 'dpm++':
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sample_scheduler = FlowDPMSolverMultistepScheduler(
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num_train_timesteps=self.num_train_timesteps,
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shift=1,
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use_dynamic_shifting=False)
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sampling_sigmas = get_sampling_sigmas(sampling_steps, shift)
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timesteps, _ = retrieve_timesteps(
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sample_scheduler,
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device=self.device,
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sigmas=sampling_sigmas)
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else:
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raise NotImplementedError("Unsupported solver.")
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# sample videos
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latents = noise
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mask1, mask2 = masks_like(noise, zero=False)
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arg_c = {'context': context, 'seq_len': seq_len}
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arg_null = {'context': context_null, 'seq_len': seq_len}
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if offload_model or self.init_on_cpu:
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self.model.to(self.device)
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torch.cuda.empty_cache()
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for _, t in enumerate(tqdm(timesteps)):
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latent_model_input = latents
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timestep = [t]
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timestep = torch.stack(timestep)
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temp_ts = (mask2[0][0][:, ::2, ::2] * timestep).flatten()
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temp_ts = torch.cat([
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temp_ts,
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temp_ts.new_ones(seq_len - temp_ts.size(0)) * timestep
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])
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timestep = temp_ts.unsqueeze(0)
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noise_pred_cond = self.model(
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latent_model_input, t=timestep, **arg_c)[0]
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noise_pred_uncond = self.model(
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latent_model_input, t=timestep, **arg_null)[0]
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noise_pred = noise_pred_uncond + guide_scale * (
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noise_pred_cond - noise_pred_uncond)
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temp_x0 = sample_scheduler.step(
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noise_pred.unsqueeze(0),
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t,
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latents[0].unsqueeze(0),
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return_dict=False,
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generator=seed_g)[0]
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latents = [temp_x0.squeeze(0)]
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x0 = latents
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if offload_model:
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self.model.cpu()
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torch.cuda.synchronize()
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torch.cuda.empty_cache()
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if self.rank == 0:
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videos = self.vae.decode(x0)
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del noise, latents
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del sample_scheduler
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if offload_model:
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gc.collect()
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torch.cuda.synchronize()
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if dist.is_initialized():
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dist.barrier()
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return videos[0] if self.rank == 0 else None
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def i2v(self,
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input_prompt,
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img,
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max_area=704 * 1280,
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frame_num=121,
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shift=5.0,
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sample_solver='unipc',
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sampling_steps=40,
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guide_scale=5.0,
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n_prompt="",
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seed=-1,
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offload_model=True):
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r"""
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Generates video frames from input image and text prompt using diffusion process.
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Args:
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input_prompt (`str`):
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Text prompt for content generation.
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img (PIL.Image.Image):
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Input image tensor. Shape: [3, H, W]
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max_area (`int`, *optional*, defaults to 704*1280):
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Maximum pixel area for latent space calculation. Controls video resolution scaling
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frame_num (`int`, *optional*, defaults to 121):
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How many frames to sample from a video. The number should be 4n+1
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shift (`float`, *optional*, defaults to 5.0):
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Noise schedule shift parameter. Affects temporal dynamics
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[NOTE]: If you want to generate a 480p video, it is recommended to set the shift value to 3.0.
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sample_solver (`str`, *optional*, defaults to 'unipc'):
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Solver used to sample the video.
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sampling_steps (`int`, *optional*, defaults to 40):
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Number of diffusion sampling steps. Higher values improve quality but slow generation
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guide_scale (`float`, *optional*, defaults 5.0):
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Classifier-free guidance scale. Controls prompt adherence vs. creativity.
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n_prompt (`str`, *optional*, defaults to ""):
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Negative prompt for content exclusion. If not given, use `config.sample_neg_prompt`
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seed (`int`, *optional*, defaults to -1):
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Random seed for noise generation. If -1, use random seed
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offload_model (`bool`, *optional*, defaults to True):
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If True, offloads models to CPU during generation to save VRAM
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Returns:
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torch.Tensor:
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Generated video frames tensor. Dimensions: (C, N H, W) where:
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- C: Color channels (3 for RGB)
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- N: Number of frames (121)
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- H: Frame height (from max_area)
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- W: Frame width (from max_area)
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"""
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# preprocess
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ih, iw = img.height, img.width
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dh, dw = self.patch_size[1] * self.vae_stride[1], self.patch_size[
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2] * self.vae_stride[2]
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ow, oh = best_output_size(iw, ih, dw, dh, max_area)
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scale = max(ow / iw, oh / ih)
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img = img.resize((round(iw * scale), round(ih * scale)), Image.LANCZOS)
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# center-crop
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x1 = (img.width - ow) // 2
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y1 = (img.height - oh) // 2
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img = img.crop((x1, y1, x1 + ow, y1 + oh))
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assert img.width == ow and img.height == oh
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# to tensor
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img = TF.to_tensor(img).sub_(0.5).div_(0.5).to(self.device).unsqueeze(1)
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F = frame_num
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seq_len = ((F - 1) // self.vae_stride[0] + 1) * (
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oh // self.vae_stride[1]) * (ow // self.vae_stride[2]) // (
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self.patch_size[1] * self.patch_size[2])
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seq_len = int(math.ceil(seq_len / self.sp_size)) * self.sp_size
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seed = seed if seed >= 0 else random.randint(0, sys.maxsize)
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seed_g = torch.Generator(device=self.device)
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seed_g.manual_seed(seed)
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noise = torch.randn(
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self.vae.model.z_dim, (F - 1) // self.vae_stride[0] + 1,
|
|
oh // self.vae_stride[1],
|
|
ow // self.vae_stride[2],
|
|
dtype=torch.float32,
|
|
generator=seed_g,
|
|
device=self.device)
|
|
|
|
if n_prompt == "":
|
|
n_prompt = self.sample_neg_prompt
|
|
|
|
# preprocess
|
|
if not self.t5_cpu:
|
|
self.text_encoder.model.to(self.device)
|
|
context = self.text_encoder([input_prompt], self.device)
|
|
context_null = self.text_encoder([n_prompt], self.device)
|
|
if offload_model:
|
|
self.text_encoder.model.cpu()
|
|
else:
|
|
context = self.text_encoder([input_prompt], torch.device('cpu'))
|
|
context_null = self.text_encoder([n_prompt], torch.device('cpu'))
|
|
context = [t.to(self.device) for t in context]
|
|
context_null = [t.to(self.device) for t in context_null]
|
|
|
|
z = self.vae.encode([img])
|
|
|
|
@contextmanager
|
|
def noop_no_sync():
|
|
yield
|
|
|
|
no_sync = getattr(self.model, 'no_sync', noop_no_sync)
|
|
|
|
# evaluation mode
|
|
with (
|
|
torch.amp.autocast('cuda', dtype=self.param_dtype),
|
|
torch.no_grad(),
|
|
no_sync(),
|
|
):
|
|
|
|
if sample_solver == 'unipc':
|
|
sample_scheduler = FlowUniPCMultistepScheduler(
|
|
num_train_timesteps=self.num_train_timesteps,
|
|
shift=1,
|
|
use_dynamic_shifting=False)
|
|
sample_scheduler.set_timesteps(
|
|
sampling_steps, device=self.device, shift=shift)
|
|
timesteps = sample_scheduler.timesteps
|
|
elif sample_solver == 'dpm++':
|
|
sample_scheduler = FlowDPMSolverMultistepScheduler(
|
|
num_train_timesteps=self.num_train_timesteps,
|
|
shift=1,
|
|
use_dynamic_shifting=False)
|
|
sampling_sigmas = get_sampling_sigmas(sampling_steps, shift)
|
|
timesteps, _ = retrieve_timesteps(
|
|
sample_scheduler,
|
|
device=self.device,
|
|
sigmas=sampling_sigmas)
|
|
else:
|
|
raise NotImplementedError("Unsupported solver.")
|
|
|
|
# sample videos
|
|
latent = noise
|
|
mask1, mask2 = masks_like([noise], zero=True)
|
|
latent = (1. - mask2[0]) * z[0] + mask2[0] * latent
|
|
|
|
arg_c = {
|
|
'context': [context[0]],
|
|
'seq_len': seq_len,
|
|
}
|
|
|
|
arg_null = {
|
|
'context': context_null,
|
|
'seq_len': seq_len,
|
|
}
|
|
|
|
if offload_model or self.init_on_cpu:
|
|
self.model.to(self.device)
|
|
torch.cuda.empty_cache()
|
|
|
|
for _, t in enumerate(tqdm(timesteps)):
|
|
latent_model_input = [latent.to(self.device)]
|
|
timestep = [t]
|
|
|
|
timestep = torch.stack(timestep).to(self.device)
|
|
|
|
temp_ts = (mask2[0][0][:, ::2, ::2] * timestep).flatten()
|
|
temp_ts = torch.cat([
|
|
temp_ts,
|
|
temp_ts.new_ones(seq_len - temp_ts.size(0)) * timestep
|
|
])
|
|
timestep = temp_ts.unsqueeze(0)
|
|
|
|
noise_pred_cond = self.model(
|
|
latent_model_input, t=timestep, **arg_c)[0]
|
|
if offload_model:
|
|
torch.cuda.empty_cache()
|
|
noise_pred_uncond = self.model(
|
|
latent_model_input, t=timestep, **arg_null)[0]
|
|
if offload_model:
|
|
torch.cuda.empty_cache()
|
|
noise_pred = noise_pred_uncond + guide_scale * (
|
|
noise_pred_cond - noise_pred_uncond)
|
|
|
|
temp_x0 = sample_scheduler.step(
|
|
noise_pred.unsqueeze(0),
|
|
t,
|
|
latent.unsqueeze(0),
|
|
return_dict=False,
|
|
generator=seed_g)[0]
|
|
latent = temp_x0.squeeze(0)
|
|
latent = (1. - mask2[0]) * z[0] + mask2[0] * latent
|
|
|
|
x0 = [latent]
|
|
del latent_model_input, timestep
|
|
|
|
if offload_model:
|
|
self.model.cpu()
|
|
torch.cuda.synchronize()
|
|
torch.cuda.empty_cache()
|
|
|
|
if self.rank == 0:
|
|
videos = self.vae.decode(x0)
|
|
|
|
del noise, latent, x0
|
|
del sample_scheduler
|
|
if offload_model:
|
|
gc.collect()
|
|
torch.cuda.synchronize()
|
|
if dist.is_initialized():
|
|
dist.barrier()
|
|
|
|
return videos[0] if self.rank == 0 else None
|