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non_learning_completion_multi_res_test.py
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non_learning_completion_multi_res_test.py
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from data_read import *
import matplotlib.pyplot as plt
import cv2
import numpy as np
from tools import *
from evaluation import *
import time
import tensorflow as tf
def do_range_projection_try(points,proj_H=64,proj_W=2048,fov_up=3.0,fov_down=-18.0):
proj_range = np.full((proj_H, proj_W), -1,dtype=np.float32)
# unprojected range (list of depths for each point)
unproj_range = np.zeros((0, 1), dtype=np.float32)
# projected point cloud xyz - [H,W,3] xyz coord (-1 is no data)
proj_xyz = np.full((proj_H, proj_W, 3), -1,dtype=np.float32)
# projected index (for each pixel, what I am in the pointcloud)
# [H,W] index (-1 is no data)
proj_idx = np.full((proj_H, proj_W), -1,
dtype=np.int32)
# for each point, where it is in the range image
proj_x = np.zeros((0, 1), dtype=np.float32) # [m, 1]: x
proj_y = np.zeros((0, 1), dtype=np.float32) # [m, 1]: y
# mask containing for each pixel, if it contains a point or not
proj_mask = np.zeros((proj_H, proj_W),dtype=np.int32)
# laser parameters
fov_up = fov_up / 180.0 * np.pi # field of view up in rad
fov_down = fov_down / 180.0 * np.pi # field of view down in rad
fov = abs(fov_down) + abs(fov_up) # get field of view total in rad
# get depth of all points
depth = np.linalg.norm(points, 2, axis=1)
# get scan components
scan_x = points[:, 0]
scan_y = points[:, 1]
scan_z = points[:, 2]
# get angles of all points
yaw = -np.arctan2(scan_y, scan_x)
pitch = np.arcsin(scan_z / depth)
# get projections in image coords
proj_x = 0.5 * (yaw / np.pi + 1.0) # in [0.0, 1.0]
proj_y = 1.0 - (pitch + abs(fov_down)) / fov # in [0.0, 1.0]
return proj_x,proj_y
def outlier_removal_mask(lidar,line_num=64,height_offset=100):
height,width=np.shape(np.squeeze(lidar))
height_bin=np.round((height-height_offset)/line_num-1)
width_bin=np.round(width*line_num/(np.sum(lidar>0.1))-1)
total_points,x_indices,y_indices,width_image,height_image=get_all_points(lidar,intrinsic)
proj_x,proj_y=do_range_projection_try(total_points)
project_x=np.zeros((height,width))
project_y=np.zeros((height,width))
project_x[y_indices,x_indices]=proj_x
project_y[y_indices,x_indices]=proj_y
lidar_pre=np.expand_dims(np.squeeze(lidar),axis=0)
lidar_pre=np.expand_dims(lidar_pre,axis=-1)
lidar_trunck=tf.image.extract_patches(images=lidar_pre,sizes=[1, height_bin*2+1, width_bin*2+1, 1],strides=[1, 1, 1, 1],rates=[1, 1, 1, 1],padding='SAME')
expand_size=(height_bin*2+1)*(width_bin*2+1)
expand_size=np.int32(expand_size)
lidar_pre_expand=tf.tile(lidar_pre.astype(np.float32),[1,1,1,expand_size])
project_x_pre=np.expand_dims(np.squeeze(project_x),axis=0)
project_x_pre=np.expand_dims(project_x_pre,axis=-1)
project_x_trunck=tf.image.extract_patches(images=project_x_pre,sizes=[1, height_bin*2+1, width_bin*2+1, 1],strides=[1, 1, 1, 1],rates=[1, 1, 1, 1],padding='SAME')
project_y_pre=np.expand_dims(np.squeeze(project_y),axis=0)
project_y_pre=np.expand_dims(project_y_pre,axis=-1)
project_y_trunck=tf.image.extract_patches(images=project_y_pre,sizes=[1, height_bin*2+1, width_bin*2+1, 1],strides=[1, 1, 1, 1],rates=[1, 1, 1, 1],padding='SAME')
height_image_pre=np.expand_dims(np.squeeze(height_image).astype(np.double),axis=0)
height_image_pre=np.expand_dims(height_image_pre,axis=-1)
height_image_trunck=tf.image.extract_patches(images=height_image_pre,sizes=[1, height_bin*2+1, width_bin*2+1, 1],strides=[1, 1, 1, 1],rates=[1, 1, 1, 1],padding='SAME')
width_image_pre=np.expand_dims(np.squeeze(width_image).astype(np.double),axis=0)
width_image_pre=np.expand_dims(width_image_pre,axis=-1)
width_image_trunck=tf.image.extract_patches(images=width_image_pre,sizes=[1, height_bin*2+1, width_bin*2+1, 1],strides=[1, 1, 1, 1],rates=[1, 1, 1, 1],padding='SAME')
lidar_residual=lidar_pre-lidar_trunck
project_x_residual=project_x_pre-project_x_trunck
project_y_residual=project_y_pre-project_y_trunck
height_image_residual=height_image_pre-height_image_trunck
width_image_residual=width_image_pre-width_image_trunck
zero_mask=np.logical_and(lidar_pre_expand>0.1,lidar_trunck>0.1)
x_mask_1=np.logical_and(project_x_residual>0.0000,width_image_residual<=0)
x_mask_2=np.logical_and(project_x_residual<0.0000,width_image_residual>=0)
x_mask=np.logical_or(x_mask_1,x_mask_2)
x_mask=np.logical_and(x_mask,zero_mask)
y_mask_1=np.logical_and(project_y_residual>0,height_image_residual<=0)
y_mask_2=np.logical_and(project_y_residual<0,height_image_residual>=0)
y_mask=np.logical_or(y_mask_1,y_mask_2)
y_mask=np.logical_and(y_mask,zero_mask)
lidar_mask=np.logical_and(lidar_residual>3.0,lidar_pre>0.01)
final_mask=np.logical_and(lidar_mask,np.logical_or(x_mask,y_mask))
final_mask=np.squeeze(final_mask)
final_mask=np.sum(final_mask,axis=-1)
final_mask=np.expand_dims(final_mask>0,axis=0)
return final_mask
evaluate=Result()
rmse_total=0
mae_total=0
irmse_total=0
imae_total=0
#validation
A=calculate_normal()
# can be 32 or 16
line_number=64
if not os.path.exists("./output"):
os.mkdir("./output")
kernelx=self_gaussian(kernel_size=7,g_range=2.5)
time_interval=[]
threshold=0.1
for i in range(1000):
print (i)
img,lidar,index,intrinsic= read_one_test(i)
# prepare camera parameters
px,py,fx,fy=construct_px_py_fx_fy(lidar,intrinsic)
# remove outliers
if i>20:
time_a=time.time()
outpier_mask=outlier_removal_mask(lidar,line_num=64,height_offset=100)
lidar_new=(1.0-outpier_mask)*lidar
# get all points
total_points,x_indices,y_indices,width_image,height_image=get_all_points(lidar_new,intrinsic)
# map points on range image
range_image,proj_xyz,proj_idx,proj_mask=do_range_projection(total_points)
# fill in range image
range_image_new=fill_spherical(range_image)
# calculate normal in spherical
normal_spherical=A.calculate_normal(range_image_new)
# put normal from spherical on original image
normal_img=put_normal_on_image(normal_spherical,x_indices,y_indices,proj_idx,proj_mask)
a=normal_img[:,:,0]
b=normal_img[:,:,1]
c=normal_img[:,:,2]
depth_map,a_list_all,b_list_all,c_list_all,height_list_offset,width_list_offset=Distance_Transform(lidar_new,a,b,c,width_image,height_image)
upper=(width_list_offset/fx*a_list_all+height_list_offset/fy*b_list_all)
lower=(width_image-px)/fx*a_list_all+(height_image-py)/fy*b_list_all+c_list_all
lower[np.logical_and(np.abs(lower)<threshold,lower>0)]=threshold
lower[np.logical_and(np.abs(lower)<threshold,lower<0)]=-threshold
residual=upper/lower
depth_predicted=depth_map+residual*depth_map
depth_predicted = cv2.filter2D(depth_predicted, -1, kernelx)
depth_predicted=np.squeeze(lidar_new)+depth_predicted*(1.0-np.squeeze(lidar_new)>0.01)
depth_predicted[depth_predicted<0.9]=0.9
depth_predicted[depth_predicted>80.0]=80.0
depth_predicted=depth_predicted*256.0
depth_predicted=depth_predicted.astype(np.uint16)
im=Image.fromarray(depth_predicted)
im.save("./output/"+index.split('/')[-1])