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import os, sys, glob
import numpy as np
from collections import OrderedDict
from decord import VideoReader, cpu
import cv2
import torch
import torchvision
sys.path.insert(1, os.path.join(sys.path[0], '..', '..'))
from lvdm.models.samplers.ddim import DDIMSampler
from lvdm.models.samplers.ddim_freetraj import DDIMSampler as DDIMFreeTrajSampler
from utils.utils_freetraj import get_freq_filter, freq_mix_3d, get_path, plan_path
def batch_ddim_sampling_freetraj(model, cond, noise_shape, n_samples=1, ddim_steps=50, ddim_eta=1.0,\
cfg_scale=1.0, temporal_cfg_scale=None, idx_list=[], input_traj=[], x_T_total=None, args=None, **kwargs):
ddim_sampler = DDIMFreeTrajSampler(model)
uncond_type = model.uncond_type
batch_size, channels, frames, h, w = noise_shape
## construct unconditional guidance
if cfg_scale != 1.0:
if uncond_type == "empty_seq":
prompts = batch_size * [""]
#prompts = N * T * [""] ## if is_imgbatch=True
uc_emb = model.get_learned_conditioning(prompts)
elif uncond_type == "zero_embed":
c_emb = cond["c_crossattn"][0] if isinstance(cond, dict) else cond
uc_emb = torch.zeros_like(c_emb)
## process image embedding token
if hasattr(model, 'embedder'):
uc_img = torch.zeros(noise_shape[0],3,224,224).to(model.device)
## img: b c h w >> b l c
uc_img = model.get_image_embeds(uc_img)
uc_emb = torch.cat([uc_emb, uc_img], dim=1)
if isinstance(cond, dict):
uc = {key:cond[key] for key in cond.keys()}
uc.update({'c_crossattn': [uc_emb]})
else:
uc = uc_emb
else:
uc = None
total_shape = [args.n_samples, 1, channels, frames, h, w]
print('total_shape', total_shape)
if x_T_total is None:
x_T_total = torch.randn(total_shape, device=model.device).repeat(1, batch_size, 1, 1, 1, 1)
noise_flow = True
if noise_flow:
print('noise_flow')
BOX_SIZE_H = input_traj[0][2] - input_traj[0][1]
BOX_SIZE_W = input_traj[0][4] - input_traj[0][3]
PATHS = plan_path(input_traj)
sub_h = int(BOX_SIZE_H * h)
sub_w = int(BOX_SIZE_W * w)
x_T_sub = torch.randn([args.n_samples, 1, channels, sub_h, sub_w], device=model.device)
for i in range(frames):
h_start = int(PATHS[i][0] * h)
h_end = h_start + sub_h
w_start = int(PATHS[i][2] * w)
w_end = w_start + sub_w
# no mix
x_T_total[:, :, :, i, h_start:h_end, w_start:w_end] = x_T_sub
filter_shape = [
1,
channels,
frames,
h,
w
]
freq_filter = get_freq_filter(
filter_shape,
device = model.device,
filter_type='butterworth',
n=4,
d_s=0.25,
d_t=0.1
)
x_T_rand = torch.randn([1, 1, channels, frames, h, w], device=model.device)
x_T_total = freq_mix_3d(x_T_total.to(dtype=torch.float32), x_T_rand, LPF=freq_filter)
# x_T = None
batch_variants = []
#batch_variants1, batch_variants2 = [], []
for _ in range(n_samples):
x_T = x_T_total[_]
if ddim_sampler is not None:
kwargs.update({"clean_cond": True})
samples, _ = ddim_sampler.sample(S=ddim_steps,
conditioning=cond,
batch_size=noise_shape[0],
shape=noise_shape[1:],
verbose=False,
unconditional_guidance_scale=cfg_scale,
unconditional_conditioning=uc,
eta=ddim_eta,
temporal_length=noise_shape[2],
conditional_guidance_scale_temporal=temporal_cfg_scale,
x_T=x_T,
idx_list=idx_list,
input_traj=input_traj,
ddim_edit = args.ddim_edit,
**kwargs
)
## reconstruct from latent to pixel space
batch_images = model.decode_first_stage_2DAE(samples)
batch_variants.append(batch_images)
## batch, <samples>, c, t, h, w
batch_variants = torch.stack(batch_variants, dim=1)
return batch_variants
def batch_ddim_sampling(model, cond, noise_shape, n_samples=1, ddim_steps=50, ddim_eta=1.0,\
cfg_scale=1.0, temporal_cfg_scale=None, **kwargs):
ddim_sampler = DDIMSampler(model)
uncond_type = model.uncond_type
batch_size = noise_shape[0]
## construct unconditional guidance
if cfg_scale != 1.0:
if uncond_type == "empty_seq":
prompts = batch_size * [""]
#prompts = N * T * [""] ## if is_imgbatch=True
uc_emb = model.get_learned_conditioning(prompts)
elif uncond_type == "zero_embed":
c_emb = cond["c_crossattn"][0] if isinstance(cond, dict) else cond
uc_emb = torch.zeros_like(c_emb)
## process image embedding token
if hasattr(model, 'embedder'):
uc_img = torch.zeros(noise_shape[0],3,224,224).to(model.device)
## img: b c h w >> b l c
uc_img = model.get_image_embeds(uc_img)
uc_emb = torch.cat([uc_emb, uc_img], dim=1)
if isinstance(cond, dict):
uc = {key:cond[key] for key in cond.keys()}
uc.update({'c_crossattn': [uc_emb]})
else:
uc = uc_emb
else:
uc = None
x_T = None
batch_variants = []
#batch_variants1, batch_variants2 = [], []
for _ in range(n_samples):
if ddim_sampler is not None:
kwargs.update({"clean_cond": True})
samples, _ = ddim_sampler.sample(S=ddim_steps,
conditioning=cond,
batch_size=noise_shape[0],
shape=noise_shape[1:],
verbose=False,
unconditional_guidance_scale=cfg_scale,
unconditional_conditioning=uc,
eta=ddim_eta,
temporal_length=noise_shape[2],
conditional_guidance_scale_temporal=temporal_cfg_scale,
x_T=x_T,
**kwargs
)
## reconstruct from latent to pixel space
batch_images = model.decode_first_stage_2DAE(samples)
batch_variants.append(batch_images)
## batch, <samples>, c, t, h, w
batch_variants = torch.stack(batch_variants, dim=1)
return batch_variants
def get_filelist(data_dir, ext='*'):
file_list = glob.glob(os.path.join(data_dir, '*.%s'%ext))
file_list.sort()
return file_list
def get_dirlist(path):
list = []
if (os.path.exists(path)):
files = os.listdir(path)
for file in files:
m = os.path.join(path,file)
if (os.path.isdir(m)):
list.append(m)
list.sort()
return list
def load_model_checkpoint(model, ckpt):
def load_checkpoint(model, ckpt, full_strict):
state_dict = torch.load(ckpt, map_location="cpu")
try:
## deepspeed
new_pl_sd = OrderedDict()
for key in state_dict['module'].keys():
new_pl_sd[key[16:]]=state_dict['module'][key]
model.load_state_dict(new_pl_sd, strict=full_strict)
except:
if "state_dict" in list(state_dict.keys()):
state_dict = state_dict["state_dict"]
model.load_state_dict(state_dict, strict=full_strict)
return model
load_checkpoint(model, ckpt, full_strict=True)
print('>>> model checkpoint loaded.')
return model
def load_prompts(prompt_file):
f = open(prompt_file, 'r')
prompt_list = []
for idx, line in enumerate(f.readlines()):
l = line.strip()
if len(l) != 0:
prompt_list.append(l)
f.close()
return prompt_list
def load_idx(prompt_file):
f = open(prompt_file, 'r')
idx_list = []
for idx, line in enumerate(f.readlines()):
l = line.strip()
if len(l) != 0:
indices = l.split(',')
indices_list = []
for index in indices:
indices_list.append(int(index))
idx_list.append(indices_list)
f.close()
return idx_list
def load_traj(prompt_file):
f = open(prompt_file, 'r')
traj_list = []
for idx, line in enumerate(f.readlines()):
l = line.strip()
if len(l) != 0:
numbers = l.split(',')
numbers_list = []
for number_index in range(len(numbers)):
if number_index == 0:
numbers_list.append(int(numbers[number_index]))
else:
numbers_list.append(float(numbers[number_index]))
traj_list.append(numbers_list)
f.close()
return traj_list
def load_video_batch(filepath_list, frame_stride, video_size=(256,256), video_frames=16):
'''
Notice about some special cases:
1. video_frames=-1 means to take all the frames (with fs=1)
2. when the total video frames is less than required, padding strategy will be used (repreated last frame)
'''
fps_list = []
batch_tensor = []
assert frame_stride > 0, "valid frame stride should be a positive interge!"
for filepath in filepath_list:
padding_num = 0
vidreader = VideoReader(filepath, ctx=cpu(0), width=video_size[1], height=video_size[0])
fps = vidreader.get_avg_fps()
total_frames = len(vidreader)
max_valid_frames = (total_frames-1) // frame_stride + 1
if video_frames < 0:
## all frames are collected: fs=1 is a must
required_frames = total_frames
frame_stride = 1
else:
required_frames = video_frames
query_frames = min(required_frames, max_valid_frames)
frame_indices = [frame_stride*i for i in range(query_frames)]
## [t,h,w,c] -> [c,t,h,w]
frames = vidreader.get_batch(frame_indices)
frame_tensor = torch.tensor(frames.asnumpy()).permute(3, 0, 1, 2).float()
frame_tensor = (frame_tensor / 255. - 0.5) * 2
if max_valid_frames < required_frames:
padding_num = required_frames - max_valid_frames
frame_tensor = torch.cat([frame_tensor, *([frame_tensor[:,-1:,:,:]]*padding_num)], dim=1)
print(f'{os.path.split(filepath)[1]} is not long enough: {padding_num} frames padded.')
batch_tensor.append(frame_tensor)
sample_fps = int(fps/frame_stride)
fps_list.append(sample_fps)
return torch.stack(batch_tensor, dim=0)
from PIL import Image
def load_image_batch(filepath_list, image_size=(256,256)):
batch_tensor = []
for filepath in filepath_list:
_, filename = os.path.split(filepath)
_, ext = os.path.splitext(filename)
if ext == '.mp4':
vidreader = VideoReader(filepath, ctx=cpu(0), width=image_size[1], height=image_size[0])
frame = vidreader.get_batch([0])
img_tensor = torch.tensor(frame.asnumpy()).squeeze(0).permute(2, 0, 1).float()
elif ext == '.png' or ext == '.jpg':
img = Image.open(filepath).convert("RGB")
rgb_img = np.array(img, np.float32)
#bgr_img = cv2.imread(filepath, cv2.IMREAD_COLOR)
#bgr_img = cv2.cvtColor(bgr_img, cv2.COLOR_BGR2RGB)
rgb_img = cv2.resize(rgb_img, (image_size[1],image_size[0]), interpolation=cv2.INTER_LINEAR)
img_tensor = torch.from_numpy(rgb_img).permute(2, 0, 1).float()
else:
print(f'ERROR: <{ext}> image loading only support format: [mp4], [png], [jpg]')
raise NotImplementedError
img_tensor = (img_tensor / 255. - 0.5) * 2
batch_tensor.append(img_tensor)
return torch.stack(batch_tensor, dim=0)
def save_videos(batch_tensors, savedir, filenames, fps=10):
# b,samples,c,t,h,w
n_samples = batch_tensors.shape[1]
for idx, vid_tensor in enumerate(batch_tensors):
video = vid_tensor.detach().cpu()
video = torch.clamp(video.float(), -1., 1.)
video = video.permute(2, 0, 1, 3, 4) # t,n,c,h,w
frame_grids = [torchvision.utils.make_grid(framesheet, nrow=int(n_samples)) for framesheet in video] #[3, 1*h, n*w]
grid = torch.stack(frame_grids, dim=0) # stack in temporal dim [t, 3, n*h, w]
grid = (grid + 1.0) / 2.0
grid = (grid * 255).to(torch.uint8).permute(0, 2, 3, 1)
savepath = os.path.join(savedir, f"{filenames[idx]}.mp4")
torchvision.io.write_video(savepath, grid, fps=fps, video_codec='h264', options={'crf': '10'})
def save_videos_with_bbox(batch_tensors, savedir, conddir, filenames, fps=10, input_traj=[]):
# b,samples,c,t,h,w
BOX_SIZE_H = input_traj[0][2] - input_traj[0][1]
BOX_SIZE_W = input_traj[0][4] - input_traj[0][3]
PATHS = plan_path(input_traj)
n_samples = batch_tensors.shape[1]
for idx, vid_tensor in enumerate(batch_tensors):
video = vid_tensor.detach().cpu()
video = torch.clamp(video.float(), -1., 1.)
video = video.permute(2, 0, 1, 3, 4) # t,n,c,h,w
h_len = video.shape[3]
w_len = video.shape[4]
sub_h = int(BOX_SIZE_H * h_len)
sub_w = int(BOX_SIZE_W * w_len)
for i in range(video.shape[1]):
single_video = video[:, i]
frame_grids = [torchvision.utils.make_grid(framesheet, nrow=int(n_samples)) for framesheet in single_video] #[3, 1*h, n*w]
grid = torch.stack(frame_grids, dim=0) # stack in temporal dim [t, 3, n*h, w]
grid = (grid + 1.0) / 2.0
grid = (grid * 255).to(torch.uint8).permute(0, 2, 3, 1)
savepath = os.path.join(savedir, f"{filenames[idx]}_{str(i)}.mp4")
torchvision.io.write_video(savepath, grid, fps=fps, video_codec='h264', options={'crf': '10'})
for j in range(video.shape[0]):
h_start = int(PATHS[j][0] * h_len)
h_end = h_start + sub_h
w_start = int(PATHS[j][2] * w_len)
w_end = w_start + sub_w
h_start = max(1, h_start)
h_end = min(h_len-1, h_end)
w_start = max(1, w_start)
w_end = min(w_len-1, w_end)
grid[j, h_start-1:h_end+1, w_start-1:w_start+2, :] = torch.ones_like(grid[j, h_start-1:h_end+1, w_start-1:w_start+2, :]) * torch.Tensor([127, 255, 127]).view(1, 1, 3)
grid[j, h_start-1:h_end+1, w_end-2:w_end+1, :] = torch.ones_like(grid[j, h_start-1:h_end+1, w_end-2:w_end+1, :]) * torch.Tensor([127, 255, 127]).view(1, 1, 3)
grid[j, h_start-1:h_start+2, w_start-1:w_end+1, :] = torch.ones_like(grid[j, h_start-1:h_start+2, w_start-1:w_end+1, :]) * torch.Tensor([127, 255, 127]).view(1, 1, 3)
grid[j, h_end-2:h_end+1, w_start-1:w_end+1, :] = torch.ones_like(grid[j, h_end-2:h_end+1, w_start-1:w_end+1, :]) * torch.Tensor([127, 255, 127]).view(1, 1, 3)
bbox_savepath = os.path.join(conddir, f"{filenames[idx]}_{str(i)}.mp4")
torchvision.io.write_video(bbox_savepath, grid, fps=fps, video_codec='h264', options={'crf': '10'})