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Open-Sora-Plan-v1-0-0 / opensora /models /frame_interpolation /interpolation.py

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	# this script is modified from https://github.com/MCG-NKU/AMT/blob/main/demos/demo_2x.py
	from json import load
	import os
	import cv2
	import sys
	import glob
	import torch
	import argparse
	import numpy as np
	import os.path as osp
	from warnings import warn
	from omegaconf import OmegaConf
	from torchvision.utils import make_grid
	sys.path.append('.')
	from utils.utils import (
	read, write,
	img2tensor, tensor2img,
	check_dim_and_resize
	)
	from utils.build_utils import build_from_cfg
	from utils.utils import InputPadder


	AMT_G = {
	'name': 'networks.AMT-G.Model',
	'params':{
	'corr_radius': 3,
	'corr_lvls': 4,
	'num_flows': 5,
	}
	}



	def init(device="cuda"):

	'''
	initialize the device and the anchor resolution.
	'''

	if device == 'cuda':
	anchor_resolution = 1024 * 512
	anchor_memory = 1500 * 1024**2
	anchor_memory_bias = 2500 * 1024**2
	vram_avail = torch.cuda.get_device_properties(device).total_memory
	print("VRAM available: {:.1f} MB".format(vram_avail / 1024 ** 2))
	else:
	# Do not resize in cpu mode
	anchor_resolution = 8192*8192
	anchor_memory = 1
	anchor_memory_bias = 0
	vram_avail = 1

	return anchor_resolution, anchor_memory, anchor_memory_bias, vram_avail

	def get_input_video_from_path(input_path, device="cuda"):

	'''
	Get the input video from the input_path.

	params:
	input_path: str, the path of the input video.
	devices: str, the device to run the model.
	returns:
	inputs: list, the list of the input frames.
	scale: float, the scale of the input frames.
	padder: InputPadder, the padder to pad the input frames.
	'''

	anchor_resolution, anchor_memory, anchor_memory_bias, vram_avail = init(device)

	if osp.splitext(input_path)[-1] in ['.mp4', '.avi', '.mov', '.mkv', '.flv', '.wmv',
	'.webm', '.MP4', '.AVI', '.MOV', '.MKV', '.FLV',
	'.WMV', '.WEBM']:

	vcap = cv2.VideoCapture(input_path)

	inputs = []
	w = int(vcap.get(cv2.CAP_PROP_FRAME_WIDTH))
	h = int(vcap.get(cv2.CAP_PROP_FRAME_HEIGHT))
	scale = anchor_resolution / (h * w) * np.sqrt((vram_avail - anchor_memory_bias) / anchor_memory)
	scale = 1 if scale > 1 else scale
	scale = 1 / np.floor(1 / np.sqrt(scale) * 16) * 16
	if scale < 1:
	print(f"Due to the limited VRAM, the video will be scaled by {scale:.2f}")
	padding = int(16 / scale)
	padder = InputPadder((h, w), padding)
	while True:
	ret, frame = vcap.read()
	if ret is False:
	break
	frame = cv2.cvtColor(frame, cv2.COLOR_BGR2RGB)
	frame_t = img2tensor(frame).to(device)
	frame_t = padder.pad(frame_t)
	inputs.append(frame_t)
	print(f'Loading the [video] from {input_path}, the number of frames [{len(inputs)}]')
	else:
	raise TypeError("Input should be a video.")

	return inputs, scale, padder


	def load_model(ckpt_path, device="cuda"):

	'''
	load the frame interpolation model.
	'''
	network_cfg = AMT_G
	network_name = network_cfg['name']
	print(f'Loading [{network_name}] from [{ckpt_path}]...')
	model = build_from_cfg(network_cfg)
	ckpt = torch.load(ckpt_path)
	model.load_state_dict(ckpt['state_dict'])
	model = model.to(device)
	model.eval()
	return model

	def interpolater(model, inputs, scale, padder, iters=1):

	'''
	interpolating with the interpolation model.

	params:
	model: nn.Module, the frame interpolation model.
	inputs: list, the list of the input frames.
	scale: float, the scale of the input frames.
	iters: int, the number of iterations of interpolation. The final frames model generating is 2 ** iters * (m - 1) + 1 and m is input frames.
	returns:
	outputs: list, the list of the output frames.
	'''

	print(f'Start frame interpolation:')
	embt = torch.tensor(1/2).float().view(1, 1, 1, 1).to(device)

	for i in range(iters):
	print(f'Iter {i+1}. input_frames={len(inputs)} output_frames={2*len(inputs)-1}')
	outputs = [inputs[0]]
	for in_0, in_1 in zip(inputs[:-1], inputs[1:]):
	in_0 = in_0.to(device)
	in_1 = in_1.to(device)
	with torch.no_grad():
	imgt_pred = model(in_0, in_1, embt, scale_factor=scale, eval=True)['imgt_pred']
	outputs += [imgt_pred.cpu(), in_1.cpu()]
	inputs = outputs

	outputs = padder.unpad(*outputs)

	return outputs

	def write(outputs, input_path, output_path, frame_rate=30):
	'''
	write results to the output_path.
	'''

	if osp.exists(output_path) is False:
	os.makedirs(output_path)


	size = outputs[0].shape[2:][::-1]

	_, file_name_with_extension = os.path.split(input_path)
	file_name, _ = os.path.splitext(file_name_with_extension)

	save_video_path = f'{output_path}/output_{file_name}.mp4'
	writer = cv2.VideoWriter(save_video_path, cv2.VideoWriter_fourcc(*"mp4v"),
	frame_rate, size)

	for i, imgt_pred in enumerate(outputs):
	imgt_pred = tensor2img(imgt_pred)
	imgt_pred = cv2.cvtColor(imgt_pred, cv2.COLOR_RGB2BGR)
	writer.write(imgt_pred)
	print(f"Demo video is saved to [{save_video_path}]")

	writer.release()


	if __name__ == "__main__":
	parser = argparse.ArgumentParser()
	parser.add_argument('--ckpt', type=str, default='amt-g.pth', help="The pretrained model.")
	parser.add_argument('--niters', type=int, default=1, help="Iter of Interpolation. The number of frames will be double after per iter.")
	parser.add_argument('--input', default="test.mp4", help="Input video.")
	parser.add_argument('--output_path', type=str, default='results', help="Output path.")
	parser.add_argument('--frame_rate', type=int, default=30, help="Frames rate of the output video.")

	args = parser.parse_args()

	device = torch.device('cuda' if torch.cuda.is_available() else 'cpu')
	ckpt_path = args.ckpt
	input_path = args.input
	output_path = args.output_path
	iters = int(args.niters)
	frame_rate = int(args.frame_rate)

	inputs, scale, padder = get_input_video_from_path(input_path, device)
	model = load_model(ckpt_path, device)
	outputs = interpolater(model, inputs, scale, padder, iters)
	write(outputs, input_path, output_path, frame_rate)