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refined gradio
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import gradio as gr
from PIL import Image
import numpy as np
from copy import deepcopy
import cv2
from objctrl_2_5d.utils.vis_camera import vis_camera_rescale
from objctrl_2_5d.utils.objmask_util import trajectory_to_camera_poses_v1
from objctrl_2_5d.utils.customized_cam import rotation, clockwise, pan_and_zoom
CAMERA_MODE = ["None", "ZoomIn", "ZoomOut", "PanRight", "PanLeft", "TiltUp", "TiltDown", "ClockWise", "Anti-CW", "Rotate60"]
zc_threshold = 0.2
depth_scale_ = 5.2
center_margin = 10
height, width = 320, 576
num_frames = 14
intrinsics = np.array([[float(width), float(width), float(width) / 2, float(height) / 2]])
intrinsics = np.repeat(intrinsics, num_frames, axis=0) # [n_frame, 4]
fx = intrinsics[0, 0] / width
fy = intrinsics[0, 1] / height
cx = intrinsics[0, 2] / width
cy = intrinsics[0, 3] / height
def process_image(raw_image):
image, points = raw_image['image'], raw_image['points']
try:
assert(len(points)) == 1, "Please select only one point"
[x1, y1, _, x2, y2, _] = points[0]
image = image.crop((x1, y1, x2, y2))
image = image.resize((width, height))
except:
image = image.resize((width, height))
return image, gr.update(value={'image': image})
# -------------- general UI functionality --------------
def get_subject_points(canvas):
return canvas["image"], canvas["points"]
def mask_image(image,
mask,
color=[255,0,0],
alpha=0.5):
""" Overlay mask on image for visualization purpose.
Args:
image (H, W, 3) or (H, W): input image
mask (H, W): mask to be overlaid
color: the color of overlaid mask
alpha: the transparency of the mask
"""
out = deepcopy(image)
img = deepcopy(image)
img[mask == 1] = color
out = cv2.addWeighted(img, alpha, out, 1-alpha, 0, out)
return out
def get_points(img,
sel_pix,
evt: gr.SelectData):
# collect the selected point
img = np.array(img)
img = deepcopy(img)
sel_pix.append(evt.index)
# only draw the last two points
# if len(sel_pix) > 2:
# sel_pix = sel_pix[-2:]
points = []
for idx, point in enumerate(sel_pix):
if idx % 2 == 0:
# draw a red circle at the handle point
cv2.circle(img, tuple(point), 10, (255, 0, 0), -1)
else:
# draw a blue circle at the handle point
cv2.circle(img, tuple(point), 10, (0, 0, 255), -1)
points.append(tuple(point))
# draw an arrow from handle point to target point
# if len(points) == idx + 1:
if idx > 0:
line_length = np.sqrt((points[idx][0] - points[idx-1][0])**2 + (points[idx][1] - points[idx-1][1])**2)
arrow_head_length = 10
tip_length = arrow_head_length / line_length
cv2.arrowedLine(img, points[idx-1], points[idx], (0, 255, 0), 4, tipLength=tip_length)
# points = []
return img if isinstance(img, np.ndarray) else np.array(img), sel_pix
# clear all handle/target points
def undo_points(original_image):
return original_image, []
def interpolate_points(points, num_points):
x = points[:, 0]
y = points[:, 1]
# Interpolating the points
t = np.linspace(0, 1, len(points))
t_new = np.linspace(0, 1, num_points)
x_new = np.interp(t_new, t, x)
y_new = np.interp(t_new, t, y)
return np.vstack((x_new, y_new)).T # []
def traj2cam(traj, depth, rescale):
if len(traj) == 0:
return None, None, 0.0, gr.update(value=CAMERA_MODE[0])
traj = np.array(traj)
trajectory = interpolate_points(traj, num_frames)
center_h_margin, center_w_margin = center_margin, center_margin
depth_center = np.mean(depth[height//2-center_h_margin:height//2+center_h_margin, width//2-center_w_margin:width//2+center_w_margin])
if rescale == 0:
rescale = 1
depth_rescale = round(depth_scale_ * rescale / depth_center, 2)
r_depth = depth * depth_rescale
zc = []
for i in range(num_frames):
zc.append(r_depth[int(trajectory[i][1]), int(trajectory[i][0])])
# print(f'zc: {zc}')
## norm zc
zc_norm = np.array(zc)
zc_grad = zc_norm[1:] - zc_norm[:-1]
zc_grad = np.abs(zc_grad)
zc_grad = zc_grad[1:] - zc_grad[:-1]
zc_grad_std = np.std(zc_grad)
if zc_grad_std > zc_threshold:
zc = [zc[0]] * num_frames
# print(f'zc_grad_std: {zc_grad_std}, zc_threshold: {zc_threshold}')
# print(f'zc: {zc}')
traj_w2c = trajectory_to_camera_poses_v1(trajectory, intrinsics, num_frames, zc=zc) # numpy: [n_frame, 4, 4]
RTs = traj_w2c[:, :3]
fig = vis_camera_rescale(RTs)
return RTs, fig, rescale, gr.update(value=CAMERA_MODE[0])
def get_rotate_cam(angle, depth):
# mean_depth = np.mean(depth * mask)
center_h_margin, center_w_margin = center_margin, center_margin
depth_center = np.mean(depth[height//2-center_h_margin:height//2+center_h_margin, width//2-center_w_margin:width//2+center_w_margin])
# print(f'rotate depth_center: {depth_center}')
RTs = rotation(num_frames, angle, depth_center, depth_center)
fig = vis_camera_rescale(RTs)
return RTs, fig
def get_clockwise_cam(angle, depth, mask):
# mask = mask.astype(np.float32) # [0, 1]
# mean_depth = np.mean(depth * mask)
# center_h_margin, center_w_margin = center_margin, center_margin
# depth_center = np.mean(depth[height//2-center_h_margin:height//2+center_h_margin, width//2-center_w_margin:width//2+center_w_margin])
RTs = clockwise(angle, num_frames)
# RTs[:, -1, -1] = mean_depth
fig = vis_camera_rescale(RTs)
return RTs, fig
def get_translate_cam(Tx, Ty, Tz, depth, mask, speed):
# mask = mask.astype(np.float32) # [0, 1]
# mean_depth = np.mean(depth * mask)
T = np.array([Tx, Ty, Tz])
T = T.reshape(3, 1)
T = T[None, ...].repeat(num_frames, axis=0)
RTs = pan_and_zoom(T, speed, n=num_frames)
# RTs[:, -1, -1] += mean_depth
fig = vis_camera_rescale(RTs)
return RTs, fig
def get_camera_pose(camera_mode):
# camera_mode = ["None", "ZoomIn", "ZoomOut", "PanLeft", "PanRight", "TiltUp", "TiltDown", "ClockWise", "Anti-CW", "Rotate60"]
def trigger_camera_pose(camera_option, depth, mask, rescale, angle, speed):
if camera_option == camera_mode[0]: # None
RTs = None
fig = None
elif camera_option == camera_mode[1]: # ZoomIn
RTs, fig = get_translate_cam(0, 0, -1, depth, mask, speed)
elif camera_option == camera_mode[2]: # ZoomOut
RTs, fig = get_translate_cam(0, 0, 1, depth, mask, speed)
elif camera_option == camera_mode[3]: # PanLeft
RTs, fig = get_translate_cam(-1, 0, 0, depth, mask, speed)
elif camera_option == camera_mode[4]: # PanRight
RTs, fig = get_translate_cam(1, 0, 0, depth, mask, speed)
elif camera_option == camera_mode[5]: # TiltUp
RTs, fig = get_translate_cam(0, 1, 0, depth, mask, speed)
elif camera_option == camera_mode[6]: # TiltDown
RTs, fig = get_translate_cam(0, -1, 0, depth, mask, speed)
elif camera_option == camera_mode[7]: # ClockWise
RTs, fig = get_clockwise_cam(-angle, depth, mask)
elif camera_option == camera_mode[8]: # Anti-CW
RTs, fig = get_clockwise_cam(angle, depth, mask)
else: # Rotate60
RTs, fig = get_rotate_cam(angle, depth)
rescale = 0.0
return RTs, fig, rescale
return trigger_camera_pose
import os
from glob import glob
import json
def get_mid_params(raw_input, canvas, mask, selected_points, camera_option, bg_mode, shared_wapring_latents, generated_video):
output_dir = "./assets/examples"
os.makedirs(output_dir, exist_ok=True)
# folders = sorted(glob(output_dir + "/*"))
folders = os.listdir(output_dir)
folders = [int(folder) for folder in folders if os.path.isdir(os.path.join(output_dir, folder))]
num = sorted(folders)[-1] + 1 if folders else 0
fout = open(os.path.join(output_dir, f'examples.json'), 'a+')
cur_folder = os.path.join(output_dir, f'{num:05d}')
os.makedirs(cur_folder, exist_ok=True)
raw_image = raw_input['image']
raw_points = raw_input['points']
seg_image = canvas['image']
seg_points = canvas['points']
mask = Image.fromarray(mask)
mask_path = os.path.join(cur_folder, 'mask.png')
mask.save(mask_path)
raw_image_path = os.path.join(cur_folder, 'raw_image.png')
seg_image_path = os.path.join(cur_folder, 'seg_image.png')
raw_image.save(os.path.join(cur_folder, 'raw_image.png'))
seg_image.save(os.path.join(cur_folder, 'seg_image.png'))
gen_path = os.path.join(cur_folder, 'generated_video.mp4')
cmd = f"cp {generated_video} {gen_path}"
os.system(cmd)
# data = [{'image': raw_image_path, 'points': raw_points},
# {'image': seg_image_path, 'points': seg_points},
# mask_path,
# str(selected_points),
# camera_option,
# bg_mode,
# gen_path]
data = {f'{num:05d}': [{'image': raw_image_path},
str(raw_points),
{'image': seg_image_path},
str(seg_points),
mask_path,
str(selected_points),
camera_option,
bg_mode,
shared_wapring_latents,
gen_path]}
fout.write(json.dumps(data) + '\n')
fout.close()