linly / NeRF /data_utils /process.py
David Victor
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import os
import glob
import tqdm
import json
import argparse
import cv2
import numpy as np
def extract_audio(path, out_path, sample_rate=16000):
print(f'[INFO] ===== extract audio from {path} to {out_path} =====')
cmd = f'ffmpeg -i {path} -f wav -ar {sample_rate} {out_path}'
os.system(cmd)
print(f'[INFO] ===== extracted audio =====')
def extract_audio_features(path, mode='wav2vec'):
print(f'[INFO] ===== extract audio labels for {path} =====')
if mode == 'wav2vec':
cmd = f'python nerf/asr.py --wav {path} --save_feats'
else: # deepspeech
cmd = f'python data_utils/deepspeech_features/extract_ds_features.py --input {path}'
os.system(cmd)
print(f'[INFO] ===== extracted audio labels =====')
def extract_images(path, out_path, fps=25):
print(f'[INFO] ===== extract images from {path} to {out_path} =====')
cmd = f'ffmpeg -i {path} -vf fps={fps} -qmin 1 -q:v 1 -start_number 0 {os.path.join(out_path, "%d.jpg")}'
os.system(cmd)
print(f'[INFO] ===== extracted images =====')
def extract_semantics(ori_imgs_dir, parsing_dir):
print(f'[INFO] ===== extract semantics from {ori_imgs_dir} to {parsing_dir} =====')
cmd = f'python data_utils/face_parsing/test.py --respath={parsing_dir} --imgpath={ori_imgs_dir}'
os.system(cmd)
print(f'[INFO] ===== extracted semantics =====')
def extract_landmarks(ori_imgs_dir):
print(f'[INFO] ===== extract face landmarks from {ori_imgs_dir} =====')
import face_alignment
try:
fa = face_alignment.FaceAlignment(face_alignment.LandmarksType._2D, flip_input=False)
except:
fa = face_alignment.FaceAlignment(face_alignment.LandmarksType.TWO_D, flip_input=False)
image_paths = glob.glob(os.path.join(ori_imgs_dir, '*.jpg'))
for image_path in tqdm.tqdm(image_paths):
input = cv2.imread(image_path, cv2.IMREAD_UNCHANGED) # [H, W, 3]
input = cv2.cvtColor(input, cv2.COLOR_BGR2RGB)
preds = fa.get_landmarks(input)
if len(preds) > 0:
lands = preds[0].reshape(-1, 2)[:,:2]
np.savetxt(image_path.replace('jpg', 'lms'), lands, '%f')
del fa
print(f'[INFO] ===== extracted face landmarks =====')
def extract_background(base_dir, ori_imgs_dir):
print(f'[INFO] ===== extract background image from {ori_imgs_dir} =====')
from sklearn.neighbors import NearestNeighbors
image_paths = glob.glob(os.path.join(ori_imgs_dir, '*.jpg'))
# only use 1/20 image_paths
image_paths = image_paths[::20]
# read one image to get H/W
tmp_image = cv2.imread(image_paths[0], cv2.IMREAD_UNCHANGED) # [H, W, 3]
h, w = tmp_image.shape[:2]
# nearest neighbors
all_xys = np.mgrid[0:h, 0:w].reshape(2, -1).transpose()
distss = []
for image_path in tqdm.tqdm(image_paths):
parse_img = cv2.imread(image_path.replace('ori_imgs', 'parsing').replace('.jpg', '.png'))
bg = (parse_img[..., 0] == 255) & (parse_img[..., 1] == 255) & (parse_img[..., 2] == 255)
fg_xys = np.stack(np.nonzero(~bg)).transpose(1, 0)
nbrs = NearestNeighbors(n_neighbors=1, algorithm='kd_tree').fit(fg_xys)
dists, _ = nbrs.kneighbors(all_xys)
distss.append(dists)
distss = np.stack(distss)
max_dist = np.max(distss, 0)
max_id = np.argmax(distss, 0)
bc_pixs = max_dist > 5
bc_pixs_id = np.nonzero(bc_pixs)
bc_ids = max_id[bc_pixs]
imgs = []
num_pixs = distss.shape[1]
for image_path in image_paths:
img = cv2.imread(image_path)
imgs.append(img)
imgs = np.stack(imgs).reshape(-1, num_pixs, 3)
bc_img = np.zeros((h*w, 3), dtype=np.uint8)
bc_img[bc_pixs_id, :] = imgs[bc_ids, bc_pixs_id, :]
bc_img = bc_img.reshape(h, w, 3)
max_dist = max_dist.reshape(h, w)
bc_pixs = max_dist > 5
bg_xys = np.stack(np.nonzero(~bc_pixs)).transpose()
fg_xys = np.stack(np.nonzero(bc_pixs)).transpose()
nbrs = NearestNeighbors(n_neighbors=1, algorithm='kd_tree').fit(fg_xys)
distances, indices = nbrs.kneighbors(bg_xys)
bg_fg_xys = fg_xys[indices[:, 0]]
bc_img[bg_xys[:, 0], bg_xys[:, 1], :] = bc_img[bg_fg_xys[:, 0], bg_fg_xys[:, 1], :]
cv2.imwrite(os.path.join(base_dir, 'bc.jpg'), bc_img)
print(f'[INFO] ===== extracted background image =====')
def extract_torso_and_gt(base_dir, ori_imgs_dir):
print(f'[INFO] ===== extract torso and gt images for {base_dir} =====')
from scipy.ndimage import binary_erosion, binary_dilation
# load bg
bg_image = cv2.imread(os.path.join(base_dir, 'bc.jpg'), cv2.IMREAD_UNCHANGED)
image_paths = glob.glob(os.path.join(ori_imgs_dir, '*.jpg'))
for image_path in tqdm.tqdm(image_paths):
# read ori image
ori_image = cv2.imread(image_path, cv2.IMREAD_UNCHANGED) # [H, W, 3]
# read semantics
seg = cv2.imread(image_path.replace('ori_imgs', 'parsing').replace('.jpg', '.png'))
head_part = (seg[..., 0] == 255) & (seg[..., 1] == 0) & (seg[..., 2] == 0)
neck_part = (seg[..., 0] == 0) & (seg[..., 1] == 255) & (seg[..., 2] == 0)
torso_part = (seg[..., 0] == 0) & (seg[..., 1] == 0) & (seg[..., 2] == 255)
bg_part = (seg[..., 0] == 255) & (seg[..., 1] == 255) & (seg[..., 2] == 255)
# get gt image
gt_image = ori_image.copy()
gt_image[bg_part] = bg_image[bg_part]
cv2.imwrite(image_path.replace('ori_imgs', 'gt_imgs'), gt_image)
# get torso image
torso_image = gt_image.copy() # rgb
torso_image[head_part] = bg_image[head_part]
torso_alpha = 255 * np.ones((gt_image.shape[0], gt_image.shape[1], 1), dtype=np.uint8) # alpha
# torso part "vertical" in-painting...
L = 8 + 1
torso_coords = np.stack(np.nonzero(torso_part), axis=-1) # [M, 2]
# lexsort: sort 2D coords first by y then by x,
# ref: https://stackoverflow.com/questions/2706605/sorting-a-2d-numpy-array-by-multiple-axes
inds = np.lexsort((torso_coords[:, 0], torso_coords[:, 1]))
torso_coords = torso_coords[inds]
# choose the top pixel for each column
u, uid, ucnt = np.unique(torso_coords[:, 1], return_index=True, return_counts=True)
top_torso_coords = torso_coords[uid] # [m, 2]
# only keep top-is-head pixels
top_torso_coords_up = top_torso_coords.copy() - np.array([1, 0])
mask = head_part[tuple(top_torso_coords_up.T)]
if mask.any():
top_torso_coords = top_torso_coords[mask]
# get the color
top_torso_colors = gt_image[tuple(top_torso_coords.T)] # [m, 3]
# construct inpaint coords (vertically up, or minus in x)
inpaint_torso_coords = top_torso_coords[None].repeat(L, 0) # [L, m, 2]
inpaint_offsets = np.stack([-np.arange(L), np.zeros(L, dtype=np.int32)], axis=-1)[:, None] # [L, 1, 2]
inpaint_torso_coords += inpaint_offsets
inpaint_torso_coords = inpaint_torso_coords.reshape(-1, 2) # [Lm, 2]
inpaint_torso_colors = top_torso_colors[None].repeat(L, 0) # [L, m, 3]
darken_scaler = 0.98 ** np.arange(L).reshape(L, 1, 1) # [L, 1, 1]
inpaint_torso_colors = (inpaint_torso_colors * darken_scaler).reshape(-1, 3) # [Lm, 3]
# set color
torso_image[tuple(inpaint_torso_coords.T)] = inpaint_torso_colors
inpaint_torso_mask = np.zeros_like(torso_image[..., 0]).astype(bool)
inpaint_torso_mask[tuple(inpaint_torso_coords.T)] = True
else:
inpaint_torso_mask = None
# neck part "vertical" in-painting...
push_down = 4
L = 48 + push_down + 1
neck_part = binary_dilation(neck_part, structure=np.array([[0, 1, 0], [0, 1, 0], [0, 1, 0]], dtype=bool), iterations=3)
neck_coords = np.stack(np.nonzero(neck_part), axis=-1) # [M, 2]
# lexsort: sort 2D coords first by y then by x,
# ref: https://stackoverflow.com/questions/2706605/sorting-a-2d-numpy-array-by-multiple-axes
inds = np.lexsort((neck_coords[:, 0], neck_coords[:, 1]))
neck_coords = neck_coords[inds]
# choose the top pixel for each column
u, uid, ucnt = np.unique(neck_coords[:, 1], return_index=True, return_counts=True)
top_neck_coords = neck_coords[uid] # [m, 2]
# only keep top-is-head pixels
top_neck_coords_up = top_neck_coords.copy() - np.array([1, 0])
mask = head_part[tuple(top_neck_coords_up.T)]
top_neck_coords = top_neck_coords[mask]
# push these top down for 4 pixels to make the neck inpainting more natural...
offset_down = np.minimum(ucnt[mask] - 1, push_down)
top_neck_coords += np.stack([offset_down, np.zeros_like(offset_down)], axis=-1)
# get the color
top_neck_colors = gt_image[tuple(top_neck_coords.T)] # [m, 3]
# construct inpaint coords (vertically up, or minus in x)
inpaint_neck_coords = top_neck_coords[None].repeat(L, 0) # [L, m, 2]
inpaint_offsets = np.stack([-np.arange(L), np.zeros(L, dtype=np.int32)], axis=-1)[:, None] # [L, 1, 2]
inpaint_neck_coords += inpaint_offsets
inpaint_neck_coords = inpaint_neck_coords.reshape(-1, 2) # [Lm, 2]
inpaint_neck_colors = top_neck_colors[None].repeat(L, 0) # [L, m, 3]
darken_scaler = 0.98 ** np.arange(L).reshape(L, 1, 1) # [L, 1, 1]
inpaint_neck_colors = (inpaint_neck_colors * darken_scaler).reshape(-1, 3) # [Lm, 3]
# set color
torso_image[tuple(inpaint_neck_coords.T)] = inpaint_neck_colors
# apply blurring to the inpaint area to avoid vertical-line artifects...
inpaint_mask = np.zeros_like(torso_image[..., 0]).astype(bool)
inpaint_mask[tuple(inpaint_neck_coords.T)] = True
blur_img = torso_image.copy()
blur_img = cv2.GaussianBlur(blur_img, (5, 5), cv2.BORDER_DEFAULT)
torso_image[inpaint_mask] = blur_img[inpaint_mask]
# set mask
mask = (neck_part | torso_part | inpaint_mask)
if inpaint_torso_mask is not None:
mask = mask | inpaint_torso_mask
torso_image[~mask] = 0
torso_alpha[~mask] = 0
cv2.imwrite(image_path.replace('ori_imgs', 'torso_imgs').replace('.jpg', '.png'), np.concatenate([torso_image, torso_alpha], axis=-1))
print(f'[INFO] ===== extracted torso and gt images =====')
def face_tracking(ori_imgs_dir):
print(f'[INFO] ===== perform face tracking =====')
image_paths = glob.glob(os.path.join(ori_imgs_dir, '*.jpg'))
# read one image to get H/W
tmp_image = cv2.imread(image_paths[0], cv2.IMREAD_UNCHANGED) # [H, W, 3]
h, w = tmp_image.shape[:2]
cmd = f'python data_utils/face_tracking/face_tracker.py --path={ori_imgs_dir} --img_h={h} --img_w={w} --frame_num={len(image_paths)}'
os.system(cmd)
print(f'[INFO] ===== finished face tracking =====')
def save_transforms(base_dir, ori_imgs_dir):
print(f'[INFO] ===== save transforms =====')
import torch
image_paths = glob.glob(os.path.join(ori_imgs_dir, '*.jpg'))
# read one image to get H/W
tmp_image = cv2.imread(image_paths[0], cv2.IMREAD_UNCHANGED) # [H, W, 3]
h, w = tmp_image.shape[:2]
params_dict = torch.load(os.path.join(base_dir, 'track_params.pt'))
focal_len = params_dict['focal']
euler_angle = params_dict['euler']
trans = params_dict['trans'] / 10.0
valid_num = euler_angle.shape[0]
def euler2rot(euler_angle):
batch_size = euler_angle.shape[0]
theta = euler_angle[:, 0].reshape(-1, 1, 1)
phi = euler_angle[:, 1].reshape(-1, 1, 1)
psi = euler_angle[:, 2].reshape(-1, 1, 1)
one = torch.ones((batch_size, 1, 1), dtype=torch.float32, device=euler_angle.device)
zero = torch.zeros((batch_size, 1, 1), dtype=torch.float32, device=euler_angle.device)
rot_x = torch.cat((
torch.cat((one, zero, zero), 1),
torch.cat((zero, theta.cos(), theta.sin()), 1),
torch.cat((zero, -theta.sin(), theta.cos()), 1),
), 2)
rot_y = torch.cat((
torch.cat((phi.cos(), zero, -phi.sin()), 1),
torch.cat((zero, one, zero), 1),
torch.cat((phi.sin(), zero, phi.cos()), 1),
), 2)
rot_z = torch.cat((
torch.cat((psi.cos(), -psi.sin(), zero), 1),
torch.cat((psi.sin(), psi.cos(), zero), 1),
torch.cat((zero, zero, one), 1)
), 2)
return torch.bmm(rot_x, torch.bmm(rot_y, rot_z))
# train_val_split = int(valid_num*0.5)
# train_val_split = valid_num - 25 * 20 # take the last 20s as valid set.
train_val_split = int(valid_num * 10 / 11)
train_ids = torch.arange(0, train_val_split)
val_ids = torch.arange(train_val_split, valid_num)
rot = euler2rot(euler_angle)
rot_inv = rot.permute(0, 2, 1)
trans_inv = -torch.bmm(rot_inv, trans.unsqueeze(2))
pose = torch.eye(4, dtype=torch.float32)
save_ids = ['train', 'val']
train_val_ids = [train_ids, val_ids]
mean_z = -float(torch.mean(trans[:, 2]).item())
for split in range(2):
transform_dict = dict()
transform_dict['focal_len'] = float(focal_len[0])
transform_dict['cx'] = float(w/2.0)
transform_dict['cy'] = float(h/2.0)
transform_dict['frames'] = []
ids = train_val_ids[split]
save_id = save_ids[split]
for i in ids:
i = i.item()
frame_dict = dict()
frame_dict['img_id'] = i
frame_dict['aud_id'] = i
pose[:3, :3] = rot_inv[i]
pose[:3, 3] = trans_inv[i, :, 0]
frame_dict['transform_matrix'] = pose.numpy().tolist()
transform_dict['frames'].append(frame_dict)
with open(os.path.join(base_dir, 'transforms_' + save_id + '.json'), 'w') as fp:
json.dump(transform_dict, fp, indent=2, separators=(',', ': '))
print(f'[INFO] ===== finished saving transforms =====')
if __name__ == '__main__':
parser = argparse.ArgumentParser()
parser.add_argument('path', type=str, help="path to video file")
parser.add_argument('--task', type=int, default=-1, help="-1 means all")
parser.add_argument('--asr', type=str, default='deepspeech', help="wav2vec or deepspeech")
opt = parser.parse_args()
base_dir = os.path.dirname(opt.path)
wav_path = os.path.join(base_dir, 'aud.wav')
ori_imgs_dir = os.path.join(base_dir, 'ori_imgs')
parsing_dir = os.path.join(base_dir, 'parsing')
gt_imgs_dir = os.path.join(base_dir, 'gt_imgs')
torso_imgs_dir = os.path.join(base_dir, 'torso_imgs')
os.makedirs(ori_imgs_dir, exist_ok=True)
os.makedirs(parsing_dir, exist_ok=True)
os.makedirs(gt_imgs_dir, exist_ok=True)
os.makedirs(torso_imgs_dir, exist_ok=True)
# extract audio
if opt.task == -1 or opt.task == 1:
extract_audio(opt.path, wav_path)
# extract audio features
if opt.task == -1 or opt.task == 2:
extract_audio_features(wav_path, mode=opt.asr)
# extract images
if opt.task == -1 or opt.task == 3:
extract_images(opt.path, ori_imgs_dir)
# face parsing
if opt.task == -1 or opt.task == 4:
extract_semantics(ori_imgs_dir, parsing_dir)
# extract bg
if opt.task == -1 or opt.task == 5:
extract_background(base_dir, ori_imgs_dir)
# extract torso images and gt_images
if opt.task == -1 or opt.task == 6:
extract_torso_and_gt(base_dir, ori_imgs_dir)
# extract face landmarks
if opt.task == -1 or opt.task == 7:
extract_landmarks(ori_imgs_dir)
# face tracking
if opt.task == -1 or opt.task == 8:
face_tracking(ori_imgs_dir)
# save transforms.json
if opt.task == -1 or opt.task == 9:
save_transforms(base_dir, ori_imgs_dir)