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open-sora / app.py

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	#!/usr/bin/env python
	"""
	This script runs a Gradio App for the Open-Sora model.

	Usage:
	python demo.py <config-path>
	"""

	import argparse
	import importlib
	import os
	import subprocess
	import sys
	import re
	import json
	import math

	import spaces
	import torch

	import gradio as gr


	MODEL_TYPES = ["v1.1"]
	CONFIG_MAP = {
	"v1.1-stage2": "configs/opensora-v1-1/inference/sample-ref.py",
	"v1.1-stage3": "configs/opensora-v1-1/inference/sample-ref.py",
	}
	HF_STDIT_MAP = {
	"v1.1-stage2": "hpcai-tech/OpenSora-STDiT-v2-stage2",
	"v1.1-stage3": "hpcai-tech/OpenSora-STDiT-v2-stage3",
	}
	RESOLUTION_MAP = {
	"144p": (144, 256),
	"240p": (240, 426),
	"360p": (360, 480),
	"480p": (480, 858),
	"720p": (720, 1280),
	"1080p": (1080, 1920)
	}


	# ============================
	# Utils
	# ============================
	def collect_references_batch(reference_paths, vae, image_size):
	from opensora.datasets.utils import read_from_path

	refs_x = []
	for reference_path in reference_paths:
	if reference_path is None:
	refs_x.append([])
	continue
	ref_path = reference_path.split(";")
	ref = []
	for r_path in ref_path:
	r = read_from_path(r_path, image_size, transform_name="resize_crop")
	r_x = vae.encode(r.unsqueeze(0).to(vae.device, vae.dtype))
	r_x = r_x.squeeze(0)
	ref.append(r_x)
	refs_x.append(ref)
	# refs_x: [batch, ref_num, C, T, H, W]
	return refs_x


	def process_mask_strategy(mask_strategy):
	mask_batch = []
	mask_strategy = mask_strategy.split(";")
	for mask in mask_strategy:
	mask_group = mask.split(",")
	assert len(mask_group) >= 1 and len(mask_group) <= 6, f"Invalid mask strategy: {mask}"
	if len(mask_group) == 1:
	mask_group.extend(["0", "0", "0", "1", "0"])
	elif len(mask_group) == 2:
	mask_group.extend(["0", "0", "1", "0"])
	elif len(mask_group) == 3:
	mask_group.extend(["0", "1", "0"])
	elif len(mask_group) == 4:
	mask_group.extend(["1", "0"])
	elif len(mask_group) == 5:
	mask_group.append("0")
	mask_batch.append(mask_group)
	return mask_batch


	def apply_mask_strategy(z, refs_x, mask_strategys, loop_i):
	masks = []
	for i, mask_strategy in enumerate(mask_strategys):
	mask = torch.ones(z.shape[2], dtype=torch.float, device=z.device)
	if mask_strategy is None:
	masks.append(mask)
	continue
	mask_strategy = process_mask_strategy(mask_strategy)
	for mst in mask_strategy:
	loop_id, m_id, m_ref_start, m_target_start, m_length, edit_ratio = mst
	loop_id = int(loop_id)
	if loop_id != loop_i:
	continue
	m_id = int(m_id)
	m_ref_start = int(m_ref_start)
	m_length = int(m_length)
	m_target_start = int(m_target_start)
	edit_ratio = float(edit_ratio)
	ref = refs_x[i][m_id] # [C, T, H, W]
	if m_ref_start < 0:
	m_ref_start = ref.shape[1] + m_ref_start
	if m_target_start < 0:
	# z: [B, C, T, H, W]
	m_target_start = z.shape[2] + m_target_start
	z[i, :, m_target_start : m_target_start + m_length] = ref[:, m_ref_start : m_ref_start + m_length]
	mask[m_target_start : m_target_start + m_length] = edit_ratio
	masks.append(mask)
	masks = torch.stack(masks)
	return masks


	def process_prompts(prompts, num_loop):
	from opensora.models.text_encoder.t5 import text_preprocessing

	ret_prompts = []
	for prompt in prompts:
	if prompt.startswith("\|0\|"):
	prompt_list = prompt.split("\|")[1:]
	text_list = []
	for i in range(0, len(prompt_list), 2):
	start_loop = int(prompt_list[i])
	text = prompt_list[i + 1]
	text = text_preprocessing(text)
	end_loop = int(prompt_list[i + 2]) if i + 2 < len(prompt_list) else num_loop
	text_list.extend([text] * (end_loop - start_loop))
	assert len(text_list) == num_loop, f"Prompt loop mismatch: {len(text_list)} != {num_loop}"
	ret_prompts.append(text_list)
	else:
	prompt = text_preprocessing(prompt)
	ret_prompts.append([prompt] * num_loop)
	return ret_prompts


	def extract_json_from_prompts(prompts):
	additional_infos = []
	ret_prompts = []
	for prompt in prompts:
	parts = re.split(r"(?=[{\[])", prompt)
	assert len(parts) <= 2, f"Invalid prompt: {prompt}"
	ret_prompts.append(parts[0])
	if len(parts) == 1:
	additional_infos.append({})
	else:
	additional_infos.append(json.loads(parts[1]))
	return ret_prompts, additional_infos


	# ============================
	# Runtime Environment
	# ============================
	def install_dependencies(enable_optimization=False):
	"""
	Install the required dependencies for the demo if they are not already installed.
	"""

	def _is_package_available(name) -> bool:
	try:
	importlib.import_module(name)
	return True
	except (ImportError, ModuleNotFoundError):
	return False

	# flash attention is needed no matter optimization is enabled or not
	# because Hugging Face transformers detects flash_attn is a dependency in STDiT
	# thus, we need to install it no matter what
	if not _is_package_available("flash_attn"):
	subprocess.run(
	f"{sys.executable} -m pip install flash-attn --no-build-isolation",
	env={"FLASH_ATTENTION_SKIP_CUDA_BUILD": "TRUE"},
	shell=True,
	)

	if enable_optimization:
	# install apex for fused layernorm
	if not _is_package_available("apex"):
	subprocess.run(
	f'{sys.executable} -m pip install -v --disable-pip-version-check --no-cache-dir --no-build-isolation --config-settings "--build-option=--cpp_ext" --config-settings "--build-option=--cuda_ext" git+https://github.com/NVIDIA/apex.git',
	shell=True,
	)

	# install ninja
	if not _is_package_available("ninja"):
	subprocess.run(f"{sys.executable} -m pip install ninja", shell=True)

	# install xformers
	if not _is_package_available("xformers"):
	subprocess.run(
	f"{sys.executable} -m pip install -v -U git+https://github.com/facebookresearch/xformers.git@main#egg=xformers",
	shell=True,
	)


	# ============================
	# Model-related
	# ============================
	def read_config(config_path):
	"""
	Read the configuration file.
	"""
	from mmengine.config import Config

	return Config.fromfile(config_path)


	def build_models(model_type, config, enable_optimization=False):
	"""
	Build the models for the given model type and configuration.
	"""
	# build vae
	from opensora.registry import MODELS, build_module

	vae = build_module(config.vae, MODELS).cuda()

	# build text encoder
	text_encoder = build_module(config.text_encoder, MODELS) # T5 must be fp32
	text_encoder.t5.model = text_encoder.t5.model.cuda()

	# build stdit
	# we load model from HuggingFace directly so that we don't need to
	# handle model download logic in HuggingFace Space
	from transformers import AutoModel

	stdit = AutoModel.from_pretrained(
	HF_STDIT_MAP[model_type],
	enable_flash_attn=enable_optimization,
	trust_remote_code=True,
	).cuda()

	# build scheduler
	from opensora.registry import SCHEDULERS

	scheduler = build_module(config.scheduler, SCHEDULERS)

	# hack for classifier-free guidance
	text_encoder.y_embedder = stdit.y_embedder

	# move modelst to device
	vae = vae.to(torch.bfloat16).eval()
	text_encoder.t5.model = text_encoder.t5.model.eval() # t5 must be in fp32
	stdit = stdit.to(torch.bfloat16).eval()

	# clear cuda
	torch.cuda.empty_cache()
	return vae, text_encoder, stdit, scheduler


	def parse_args():
	parser = argparse.ArgumentParser()
	parser.add_argument(
	"--model-type",
	default="v1.1-stage3",
	choices=MODEL_TYPES,
	help=f"The type of model to run for the Gradio App, can only be {MODEL_TYPES}",
	)
	parser.add_argument("--output", default="./outputs", type=str, help="The path to the output folder")
	parser.add_argument("--port", default=None, type=int, help="The port to run the Gradio App on.")
	parser.add_argument("--host", default=None, type=str, help="The host to run the Gradio App on.")
	parser.add_argument("--share", action="store_true", help="Whether to share this gradio demo.")
	parser.add_argument(
	"--enable-optimization",
	action="store_true",
	help="Whether to enable optimization such as flash attention and fused layernorm",
	)
	return parser.parse_args()


	# ============================
	# Main Gradio Script
	# ============================
	# as `run_inference` needs to be wrapped by `spaces.GPU` and the input can only be the prompt text
	# so we can't pass the models to `run_inference` as arguments.
	# instead, we need to define them globally so that we can access these models inside `run_inference`

	# read config
	args = parse_args()
	config = read_config(CONFIG_MAP[args.model_type])

	# make outputs dir
	os.makedirs(args.output, exist_ok=True)

	# disable torch jit as it can cause failure in gradio SDK
	# gradio sdk uses torch with cuda 11.3
	torch.jit._state.disable()

	# set up
	install_dependencies(enable_optimization=args.enable_optimization)

	# import after installation
	from opensora.datasets import IMG_FPS, save_sample
	from opensora.utils.misc import to_torch_dtype

	# some global variables
	dtype = to_torch_dtype(config.dtype)
	device = torch.device("cuda")

	# build model
	vae, text_encoder, stdit, scheduler = build_models(args.model_type, config, enable_optimization=args.enable_optimization)


	@spaces.GPU(duration=200)
	def run_inference(mode, prompt_text, resolution, length, reference_image):
	with torch.inference_mode():
	# ======================
	# 1. Preparation
	# ======================
	# parse the inputs
	resolution = RESOLUTION_MAP[resolution]

	# compute number of loops
	num_seconds = int(length.rstrip('s'))
	total_number_of_frames = num_seconds * config.fps / config.frame_interval
	num_loop = math.ceil(total_number_of_frames / config.num_frames)

	# prepare model args
	model_args = dict()
	height = torch.tensor([resolution[0]], device=device, dtype=dtype)
	width = torch.tensor([resolution[1]], device=device, dtype=dtype)
	num_frames = torch.tensor([config.num_frames], device=device, dtype=dtype)
	ar = torch.tensor([resolution[0] / resolution[1]], device=device, dtype=dtype)
	if config.num_frames == 1:
	config.fps = IMG_FPS
	fps = torch.tensor([config.fps], device=device, dtype=dtype)
	model_args["height"] = height
	model_args["width"] = width
	model_args["num_frames"] = num_frames
	model_args["ar"] = ar
	model_args["fps"] = fps

	# compute latent size
	input_size = (config.num_frames, *resolution)
	latent_size = vae.get_latent_size(input_size)

	# process prompt
	prompt_raw = [prompt_text]
	prompt_raw, _ = extract_json_from_prompts(prompt_raw)
	prompt_loops = process_prompts(prompt_raw, num_loop)
	video_clips = []

	# prepare mask strategy
	if mode == "Text2Video":
	mask_strategy = [None]
	elif mode == "Image2Video":
	mask_strategy = ['0']
	else:
	raise ValueError(f"Invalid mode: {mode}")

	# =========================
	# 2. Load reference images
	# =========================
	if mode == "Text2Video":
	refs_x = collect_references_batch([None], vae, resolution)
	elif mode == "Image2Video":
	# save image to disk
	from PIL import Image
	im = Image.fromarray(reference_image)
	im.save("test.jpg")
	refs_x = collect_references_batch(["test.jpg"], vae, resolution)
	else:
	raise ValueError(f"Invalid mode: {mode}")

	# 4.3. long video generation
	for loop_i in range(num_loop):
	# 4.4 sample in hidden space
	batch_prompts = [prompt[loop_i] for prompt in prompt_loops]
	z = torch.randn(len(batch_prompts), vae.out_channels, *latent_size, device=device, dtype=dtype)

	# 4.5. apply mask strategy
	masks = None

	# if cfg.reference_path is not None:
	if loop_i > 0:
	ref_x = vae.encode(video_clips[-1])
	for j, refs in enumerate(refs_x):
	if refs is None:
	refs_x[j] = [ref_x[j]]
	else:
	refs.append(ref_x[j])
	if mask_strategy[j] is None:
	mask_strategy[j] = ""
	else:
	mask_strategy[j] += ";"
	mask_strategy[
	j
	] += f"{loop_i},{len(refs)-1},-{config.condition_frame_length},0,{config.condition_frame_length}"

	masks = apply_mask_strategy(z, refs_x, mask_strategy, loop_i)

	# 4.6. diffusion sampling
	samples = scheduler.sample(
	stdit,
	text_encoder,
	z=z,
	prompts=batch_prompts,
	device=device,
	additional_args=model_args,
	mask=masks, # scheduler must support mask
	)
	samples = vae.decode(samples.to(dtype))
	video_clips.append(samples)

	# 4.7. save video
	if loop_i == num_loop - 1:
	video_clips_list = [
	video_clips[0][0]] + [video_clips[i][0][:, config.condition_frame_length :]
	for i in range(1, num_loop)
	]
	video = torch.cat(video_clips_list, dim=1)
	save_path = f"{args.output}/sample"
	saved_path = save_sample(video, fps=config.fps // config.frame_interval, save_path=save_path, force_video=True)
	return saved_path


	def main():
	# create demo
	with gr.Blocks() as demo:
	with gr.Row():
	with gr.Column():
	gr.HTML(
	"""
	<div style='text-align: center;'>
	<p align="center">
	<img src="https://github.com/hpcaitech/Open-Sora/raw/main/assets/readme/icon.png" width="250"/>
	</p>
	<div style="display: flex; gap: 10px; justify-content: center;">
	<a href="https://github.com/hpcaitech/Open-Sora/stargazers"><img src="https://img.shields.io/github/stars/hpcaitech/Open-Sora?style=social"></a>
	<a href="https://hpcaitech.github.io/Open-Sora/"><img src="https://img.shields.io/badge/Gallery-View-orange?logo=&amp"></a>
	<a href="https://discord.gg/kZakZzrSUT"><img src="https://img.shields.io/badge/Discord-join-blueviolet?logo=discord&amp"></a>
	<a href="https://join.slack.com/t/colossalaiworkspace/shared_invite/zt-247ipg9fk-KRRYmUl~u2ll2637WRURVA"><img src="https://img.shields.io/badge/Slack-ColossalAI-blueviolet?logo=slack&amp"></a>
	<a href="https://twitter.com/yangyou1991/status/1769411544083996787?s=61&t=jT0Dsx2d-MS5vS9rNM5e5g"><img src="https://img.shields.io/badge/Twitter-Discuss-blue?logo=twitter&amp"></a>
	<a href="https://raw.githubusercontent.com/hpcaitech/public_assets/main/colossalai/img/WeChat.png"><img src="https://img.shields.io/badge/微信-小助手加群-green?logo=wechat&amp"></a>
	<a href="https://hpc-ai.com/blog/open-sora-v1.0"><img src="https://img.shields.io/badge/Open_Sora-Blog-blue"></a>
	</div>
	<h1 style='margin-top: 5px;'>Open-Sora: Democratizing Efficient Video Production for All</h1>
	</div>
	"""
	)

	with gr.Row():
	with gr.Column():
	mode = gr.Radio(
	choices=["Text2Video", "Image2Video"],
	value="Text2Video",
	label="Usage",
	info="Choose your usage scenario",
	)
	prompt_text = gr.Textbox(
	label="Prompt",
	placeholder="Describe your video here",
	lines=4,
	)
	resolution = gr.Radio(
	choices=["144p", "240p", "360p", "480p", "720p", "1080p"],
	value="144p",
	label="Resolution",
	)
	length = gr.Radio(
	choices=["2s", "4s", "8s"],
	value="2s",
	label="Video Length",
	info="8s may fail as Hugging Face ZeroGPU has the limitation of max 200 seconds inference time."
	)

	reference_image = gr.Image(
	label="Reference Image (only used for Image2Video)",
	)

	with gr.Column():
	output_video = gr.Video(
	label="Output Video",
	height="100%"
	)

	with gr.Row():
	submit_button = gr.Button("Generate video")


	submit_button.click(
	fn=run_inference,
	inputs=[mode, prompt_text, resolution, length, reference_image],
	outputs=output_video
	)

	# launch
	demo.launch(server_port=args.port, server_name=args.host, share=args.share)


	if __name__ == "__main__":
	main()