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mlsd / utils.py

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	'''
	M-LSD
	Copyright 2021-present NAVER Corp.
	Apache License v2.0
	'''
	import os
	import numpy as np
	import cv2
	import tensorflow as tf


	def pred_lines(image, interpreter, input_details, output_details, input_shape=[512, 512], score_thr=0.10, dist_thr=20.0):
	h, w, _ = image.shape
	h_ratio, w_ratio = [h / input_shape[0], w / input_shape[1]]

	resized_image = np.concatenate([cv2.resize(image, (input_shape[0], input_shape[1]), interpolation=cv2.INTER_AREA), np.ones([input_shape[0], input_shape[1], 1])], axis=-1)
	batch_image = np.expand_dims(resized_image, axis=0).astype('float32')
	interpreter.set_tensor(input_details[0]['index'], batch_image)
	interpreter.invoke()

	pts = interpreter.get_tensor(output_details[0]['index'])[0]
	pts_score = interpreter.get_tensor(output_details[1]['index'])[0]
	vmap = interpreter.get_tensor(output_details[2]['index'])[0]

	start = vmap[:,:,:2]
	end = vmap[:,:,2:]
	dist_map = np.sqrt(np.sum((start - end) ** 2, axis=-1))

	segments_list = []
	for center, score in zip(pts, pts_score):
	y, x = center
	distance = dist_map[y, x]
	if score > score_thr and distance > dist_thr:
	disp_x_start, disp_y_start, disp_x_end, disp_y_end = vmap[y, x, :]
	x_start = x + disp_x_start
	y_start = y + disp_y_start
	x_end = x + disp_x_end
	y_end = y + disp_y_end
	segments_list.append([x_start, y_start, x_end, y_end])

	lines = 2 * np.array(segments_list) # 256 > 512
	lines[:,0] = lines[:,0] * w_ratio
	lines[:,1] = lines[:,1] * h_ratio
	lines[:,2] = lines[:,2] * w_ratio
	lines[:,3] = lines[:,3] * h_ratio

	return lines


	def pred_squares(image,
	interpreter,
	input_details,
	output_details,
	input_shape=[512, 512],
	params={'score': 0.06,
	'outside_ratio': 0.28,
	'inside_ratio': 0.45,
	'w_overlap': 0.0,
	'w_degree': 1.95,
	'w_length': 0.0,
	'w_area': 1.86,
	'w_center': 0.14}):
	h, w, _ = image.shape
	original_shape = [h, w]

	resized_image = np.concatenate([cv2.resize(image, (input_shape[0], input_shape[1]), interpolation=cv2.INTER_AREA), np.ones([input_shape[0], input_shape[1], 1])], axis=-1)
	batch_image = np.expand_dims(resized_image, axis=0).astype('float32')
	interpreter.set_tensor(input_details[0]['index'], batch_image)
	interpreter.invoke()

	pts = interpreter.get_tensor(output_details[0]['index'])[0]
	pts_score = interpreter.get_tensor(output_details[1]['index'])[0]
	vmap = interpreter.get_tensor(output_details[2]['index'])[0]

	start = vmap[:,:,:2] # (x, y)
	end = vmap[:,:,2:] # (x, y)
	dist_map = np.sqrt(np.sum((start - end) ** 2, axis=-1))

	junc_list = []
	segments_list = []
	for junc, score in zip(pts, pts_score):
	y, x = junc
	distance = dist_map[y, x]
	if score > params['score'] and distance > 20.0:
	junc_list.append([x, y])
	disp_x_start, disp_y_start, disp_x_end, disp_y_end = vmap[y, x, :]
	d_arrow = 1.0
	x_start = x + d_arrow * disp_x_start
	y_start = y + d_arrow * disp_y_start
	x_end = x + d_arrow * disp_x_end
	y_end = y + d_arrow * disp_y_end
	segments_list.append([x_start, y_start, x_end, y_end])

	segments = np.array(segments_list)

	####### post processing for squares
	# 1. get unique lines
	point = np.array([[0, 0]])
	point = point[0]
	start = segments[:,:2]
	end = segments[:,2:]
	diff = start - end
	a = diff[:, 1]
	b = -diff[:, 0]
	c = a * start[:,0] + b * start[:,1]

	d = np.abs(a * point[0] + b * point[1] - c) / np.sqrt(a 2 + b 2 + 1e-10)
	theta = np.arctan2(diff[:,0], diff[:,1]) * 180 / np.pi
	theta[theta < 0.0] += 180
	hough = np.concatenate([d[:,None], theta[:,None]], axis=-1)

	d_quant = 1
	theta_quant = 2
	hough[:,0] //= d_quant
	hough[:,1] //= theta_quant
	_, indices, counts = np.unique(hough, axis=0, return_index=True, return_counts=True)

	acc_map = np.zeros([512 // d_quant + 1, 360 // theta_quant + 1], dtype='float32')
	idx_map = np.zeros([512 // d_quant + 1, 360 // theta_quant + 1], dtype='int32') - 1
	yx_indices = hough[indices,:].astype('int32')
	acc_map[yx_indices[:,0], yx_indices[:,1]] = counts
	idx_map[yx_indices[:,0], yx_indices[:,1]] = indices

	acc_map_np = acc_map
	acc_map = acc_map[None,:,:,None]

	### fast suppression using tensorflow op
	acc_map = tf.constant(acc_map, dtype=tf.float32)
	max_acc_map = tf.keras.layers.MaxPool2D(pool_size=(5,5), strides=1, padding='same')(acc_map)
	acc_map = acc_map * tf.cast(tf.math.equal(acc_map, max_acc_map), tf.float32)
	flatten_acc_map = tf.reshape(acc_map, [1, -1])
	topk_values, topk_indices = tf.math.top_k(flatten_acc_map, k=len(pts))
	_, h, w, _ = acc_map.shape
	y = tf.expand_dims(topk_indices // w, axis=-1)
	x = tf.expand_dims(topk_indices % w, axis=-1)
	yx = tf.concat([y, x], axis=-1)
	###

	yx = yx[0].numpy()
	indices = idx_map[yx[:,0], yx[:,1]]
	topk_values = topk_values.numpy()[0]
	basis = 5 // 2

	merged_segments = []
	for yx_pt, max_indice, value in zip(yx, indices, topk_values):
	y, x = yx_pt
	if max_indice == -1 or value == 0:
	continue
	segment_list = []
	for y_offset in range(-basis, basis+1):
	for x_offset in range(-basis, basis+1):
	indice = idx_map[y+y_offset,x+x_offset]
	cnt = int(acc_map_np[y+y_offset,x+x_offset])
	if indice != -1:
	segment_list.append(segments[indice])
	if cnt > 1:
	check_cnt = 1
	current_hough = hough[indice]
	for new_indice, new_hough in enumerate(hough):
	if (current_hough == new_hough).all() and indice != new_indice:
	segment_list.append(segments[new_indice])
	check_cnt += 1
	if check_cnt == cnt:
	break
	group_segments = np.array(segment_list).reshape([-1, 2])
	sorted_group_segments = np.sort(group_segments, axis=0)
	x_min, y_min = sorted_group_segments[0,:]
	x_max, y_max = sorted_group_segments[-1,:]

	deg = theta[max_indice]
	if deg >= 90:
	merged_segments.append([x_min, y_max, x_max, y_min])
	else:
	merged_segments.append([x_min, y_min, x_max, y_max])

	# 2. get intersections
	new_segments = np.array(merged_segments) # (x1, y1, x2, y2)
	start = new_segments[:,:2] # (x1, y1)
	end = new_segments[:,2:] # (x2, y2)
	new_centers = (start + end) / 2.0
	diff = start - end
	dist_segments = np.sqrt(np.sum(diff ** 2, axis=-1))

	# ax + by = c
	a = diff[:,1]
	b = -diff[:,0]
	c = a * start[:,0] + b * start[:,1]
	pre_det = a[:,None] * b[None,:]
	det = pre_det - np.transpose(pre_det)

	pre_inter_y = a[:,None] * c[None,:]
	inter_y = (pre_inter_y - np.transpose(pre_inter_y)) / (det + 1e-10)
	pre_inter_x = c[:,None] * b[None,:]
	inter_x = (pre_inter_x - np.transpose(pre_inter_x)) / (det + 1e-10)
	inter_pts = np.concatenate([inter_x[:,:,None], inter_y[:,:,None]], axis=-1).astype('int32')

	# 3. get corner information
	# 3.1 get distance
	'''
	dist_segments:
	\| dist(0), dist(1), dist(2), ...\|
	dist_inter_to_segment1:
	\| dist(inter,0), dist(inter,0), dist(inter,0), ... \|
	\| dist(inter,1), dist(inter,1), dist(inter,1), ... \|
	...
	dist_inter_to_semgnet2:
	\| dist(inter,0), dist(inter,1), dist(inter,2), ... \|
	\| dist(inter,0), dist(inter,1), dist(inter,2), ... \|
	...
	'''

	dist_inter_to_segment1_start = np.sqrt(np.sum(((inter_pts - start[:,None,:]) ** 2), axis=-1, keepdims=True)) # [n_batch, n_batch, 1]
	dist_inter_to_segment1_end = np.sqrt(np.sum(((inter_pts - end[:,None,:]) ** 2), axis=-1, keepdims=True)) # [n_batch, n_batch, 1]
	dist_inter_to_segment2_start = np.sqrt(np.sum(((inter_pts - start[None,:,:]) ** 2), axis=-1, keepdims=True)) # [n_batch, n_batch, 1]
	dist_inter_to_segment2_end = np.sqrt(np.sum(((inter_pts - end[None,:,:]) ** 2), axis=-1, keepdims=True)) # [n_batch, n_batch, 1]

	# sort ascending
	dist_inter_to_segment1 = np.sort(np.concatenate([dist_inter_to_segment1_start, dist_inter_to_segment1_end], axis=-1), axis=-1) # [n_batch, n_batch, 2]
	dist_inter_to_segment2 = np.sort(np.concatenate([dist_inter_to_segment2_start, dist_inter_to_segment2_end], axis=-1), axis=-1) # [n_batch, n_batch, 2]

	# 3.2 get degree
	inter_to_start = new_centers[:,None,:] - inter_pts
	deg_inter_to_start = np.arctan2(inter_to_start[:,:,1], inter_to_start[:,:,0]) * 180 / np.pi
	deg_inter_to_start[deg_inter_to_start < 0.0] += 360
	inter_to_end = new_centers[None,:,:] - inter_pts
	deg_inter_to_end = np.arctan2(inter_to_end[:,:,1], inter_to_end[:,:,0]) * 180 / np.pi
	deg_inter_to_end[deg_inter_to_end < 0.0] += 360

	'''
	0 -- 1
	\| \|
	3 -- 2
	'''
	# rename variables
	deg1_map, deg2_map = deg_inter_to_start, deg_inter_to_end
	# sort deg ascending
	deg_sort = np.sort(np.concatenate([deg1_map[:,:,None], deg2_map[:,:,None]], axis=-1), axis=-1)

	deg_diff_map = np.abs(deg1_map - deg2_map)
	# we only consider the smallest degree of intersect
	deg_diff_map[deg_diff_map > 180] = 360 - deg_diff_map[deg_diff_map > 180]

	# define available degree range
	deg_range = [60, 120]

	corner_dict = {corner_info: [] for corner_info in range(4)}
	inter_points = []
	for i in range(inter_pts.shape[0]):
	for j in range(i + 1, inter_pts.shape[1]):
	# i, j > line index, always i < j
	x, y = inter_pts[i, j, :]
	deg1, deg2 = deg_sort[i, j, :]
	deg_diff = deg_diff_map[i, j]

	check_degree = deg_diff > deg_range[0] and deg_diff < deg_range[1]

	outside_ratio = params['outside_ratio'] # over ratio >>> drop it!
	inside_ratio = params['inside_ratio'] # over ratio >>> drop it!
	check_distance = ((dist_inter_to_segment1[i,j,1] >= dist_segments[i] and \
	dist_inter_to_segment1[i,j,0] <= dist_segments[i] * outside_ratio) or \
	(dist_inter_to_segment1[i,j,1] <= dist_segments[i] and \
	dist_inter_to_segment1[i,j,0] <= dist_segments[i] * inside_ratio)) and \
	((dist_inter_to_segment2[i,j,1] >= dist_segments[j] and \
	dist_inter_to_segment2[i,j,0] <= dist_segments[j] * outside_ratio) or \
	(dist_inter_to_segment2[i,j,1] <= dist_segments[j] and \
	dist_inter_to_segment2[i,j,0] <= dist_segments[j] * inside_ratio))

	if check_degree and check_distance:
	corner_info = None

	if (deg1 >= 0 and deg1 <= 45 and deg2 >=45 and deg2 <= 120) or \
	(deg2 >= 315 and deg1 >= 45 and deg1 <= 120):
	corner_info, color_info = 0, 'blue'
	elif (deg1 >= 45 and deg1 <= 125 and deg2 >= 125 and deg2 <= 225):
	corner_info, color_info = 1, 'green'
	elif (deg1 >= 125 and deg1 <= 225 and deg2 >= 225 and deg2 <= 315):
	corner_info, color_info = 2, 'black'
	elif (deg1 >= 0 and deg1 <= 45 and deg2 >= 225 and deg2 <= 315) or \
	(deg2 >= 315 and deg1 >= 225 and deg1 <= 315):
	corner_info, color_info = 3, 'cyan'
	else:
	corner_info, color_info = 4, 'red' # we don't use it
	continue

	corner_dict[corner_info].append([x, y, i, j])
	inter_points.append([x, y])

	square_list = []
	connect_list = []
	segments_list = []
	for corner0 in corner_dict[0]:
	for corner1 in corner_dict[1]:
	connect01 = False
	for corner0_line in corner0[2:]:
	if corner0_line in corner1[2:]:
	connect01 = True
	break
	if connect01:
	for corner2 in corner_dict[2]:
	connect12 = False
	for corner1_line in corner1[2:]:
	if corner1_line in corner2[2:]:
	connect12 = True
	break
	if connect12:
	for corner3 in corner_dict[3]:
	connect23 = False
	for corner2_line in corner2[2:]:
	if corner2_line in corner3[2:]:
	connect23 = True
	break
	if connect23:
	for corner3_line in corner3[2:]:
	if corner3_line in corner0[2:]:
	# SQUARE!!!
	'''
	0 -- 1
	\| \|
	3 -- 2
	square_list:
	order: 0 > 1 > 2 > 3
	\| x0, y0, x1, y1, x2, y2, x3, y3 \|
	\| x0, y0, x1, y1, x2, y2, x3, y3 \|
	...
	connect_list:
	order: 01 > 12 > 23 > 30
	\| line_idx01, line_idx12, line_idx23, line_idx30 \|
	\| line_idx01, line_idx12, line_idx23, line_idx30 \|
	...
	segments_list:
	order: 0 > 1 > 2 > 3
	\| line_idx0_i, line_idx0_j, line_idx1_i, line_idx1_j, line_idx2_i, line_idx2_j, line_idx3_i, line_idx3_j \|
	\| line_idx0_i, line_idx0_j, line_idx1_i, line_idx1_j, line_idx2_i, line_idx2_j, line_idx3_i, line_idx3_j \|
	...
	'''
	square_list.append(corner0[:2] + corner1[:2] + corner2[:2] + corner3[:2])
	connect_list.append([corner0_line, corner1_line, corner2_line, corner3_line])
	segments_list.append(corner0[2:] + corner1[2:] + corner2[2:] + corner3[2:])

	def check_outside_inside(segments_info, connect_idx):
	# return 'outside or inside', min distance, cover_param, peri_param
	if connect_idx == segments_info[0]:
	check_dist_mat = dist_inter_to_segment1
	else:
	check_dist_mat = dist_inter_to_segment2

	i, j = segments_info
	min_dist, max_dist = check_dist_mat[i, j, :]
	connect_dist = dist_segments[connect_idx]
	if max_dist > connect_dist:
	return 'outside', min_dist, 0, 1
	else:
	return 'inside', min_dist, -1, -1


	top_square = None

	try:
	map_size = input_shape[0] / 2
	squares = np.array(square_list).reshape([-1,4,2])
	score_array = []
	connect_array = np.array(connect_list)
	segments_array = np.array(segments_list).reshape([-1,4,2])

	# get degree of corners:
	squares_rollup = np.roll(squares, 1, axis=1)
	squares_rolldown = np.roll(squares, -1, axis=1)
	vec1 = squares_rollup - squares
	normalized_vec1 = vec1 / (np.linalg.norm(vec1, axis=-1, keepdims=True) + 1e-10)
	vec2 = squares_rolldown - squares
	normalized_vec2 = vec2 / (np.linalg.norm(vec2, axis=-1, keepdims=True) + 1e-10)
	inner_products = np.sum(normalized_vec1 * normalized_vec2, axis=-1) # [n_squares, 4]
	squares_degree = np.arccos(inner_products) * 180 / np.pi # [n_squares, 4]

	# get square score
	overlap_scores = []
	degree_scores = []
	length_scores = []

	for connects, segments, square, degree in zip(connect_array, segments_array, squares, squares_degree):
	'''
	0 -- 1
	\| \|
	3 -- 2

	# segments: [4, 2]
	# connects: [4]
	'''

	###################################### OVERLAP SCORES
	cover = 0
	perimeter = 0
	# check 0 > 1 > 2 > 3
	square_length = []

	for start_idx in range(4):
	end_idx = (start_idx + 1) % 4

	connect_idx = connects[start_idx] # segment idx of segment01
	start_segments = segments[start_idx]
	end_segments = segments[end_idx]

	start_point = square[start_idx]
	end_point = square[end_idx]

	# check whether outside or inside
	start_position, start_min, start_cover_param, start_peri_param = check_outside_inside(start_segments, connect_idx)
	end_position, end_min, end_cover_param, end_peri_param = check_outside_inside(end_segments, connect_idx)

	cover += dist_segments[connect_idx] + start_cover_param * start_min + end_cover_param * end_min
	perimeter += dist_segments[connect_idx] + start_peri_param * start_min + end_peri_param * end_min

	square_length.append(dist_segments[connect_idx] + start_peri_param * start_min + end_peri_param * end_min)

	overlap_scores.append(cover / perimeter)
	######################################
	###################################### DEGREE SCORES
	'''
	deg0 vs deg2
	deg1 vs deg3
	'''
	deg0, deg1, deg2, deg3 = degree
	deg_ratio1 = deg0 / deg2
	if deg_ratio1 > 1.0:
	deg_ratio1 = 1 / deg_ratio1
	deg_ratio2 = deg1 / deg3
	if deg_ratio2 > 1.0:
	deg_ratio2 = 1 / deg_ratio2
	degree_scores.append((deg_ratio1 + deg_ratio2) / 2)
	######################################
	###################################### LENGTH SCORES
	'''
	len0 vs len2
	len1 vs len3
	'''
	len0, len1, len2, len3 = square_length
	len_ratio1 = len0 / len2 if len2 > len0 else len2 / len0
	len_ratio2 = len1 / len3 if len3 > len1 else len3 / len1
	length_scores.append((len_ratio1 + len_ratio2) / 2)

	######################################

	overlap_scores = np.array(overlap_scores)
	overlap_scores /= np.max(overlap_scores)

	degree_scores = np.array(degree_scores)
	#degree_scores /= np.max(degree_scores)

	length_scores = np.array(length_scores)

	###################################### AREA SCORES
	area_scores = np.reshape(squares, [-1, 4, 2])
	area_x = area_scores[:,:,0]
	area_y = area_scores[:,:,1]
	correction = area_x[:,-1] * area_y[:,0] - area_y[:,-1] * area_x[:,0]
	area_scores = np.sum(area_x[:,:-1] * area_y[:,1:], axis=-1) - np.sum(area_y[:,:-1] * area_x[:,1:], axis=-1)
	area_scores = 0.5 * np.abs(area_scores + correction)
	area_scores /= (map_size * map_size) #np.max(area_scores)
	######################################

	###################################### CENTER SCORES
	centers = np.array([[256 // 2, 256 // 2]], dtype='float32') # [1, 2]
	# squares: [n, 4, 2]
	square_centers = np.mean(squares, axis=1) # [n, 2]
	center2center = np.sqrt(np.sum((centers - square_centers) ** 2))
	center_scores = center2center / (map_size / np.sqrt(2.0))


	'''
	score_w = [overlap, degree, area, center, length]
	'''
	score_w = [0.0, 1.0, 10.0, 0.5, 1.0]
	score_array = params['w_overlap'] * overlap_scores \
	+ params['w_degree'] * degree_scores \
	+ params['w_area'] * area_scores \
	- params['w_center'] * center_scores \
	+ params['w_length'] * length_scores

	best_square = []

	sorted_idx = np.argsort(score_array)[::-1]
	score_array = score_array[sorted_idx]
	squares = squares[sorted_idx]

	except Exception as e:
	pass

	try:
	new_segments[:,0] = new_segments[:,0] * 2 / input_shape[1] * original_shape[1]
	new_segments[:,1] = new_segments[:,1] * 2 / input_shape[0] * original_shape[0]
	new_segments[:,2] = new_segments[:,2] * 2 / input_shape[1] * original_shape[1]
	new_segments[:,3] = new_segments[:,3] * 2 / input_shape[0] * original_shape[0]
	except:
	new_segments = []

	try:
	squares[:,:,0] = squares[:,:,0] * 2 / input_shape[1] * original_shape[1]
	squares[:,:,1] = squares[:,:,1] * 2 / input_shape[0] * original_shape[0]
	except:
	squares = []
	score_array = []

	try:
	inter_points = np.array(inter_points)
	inter_points[:,0] = inter_points[:,0] * 2 / input_shape[1] * original_shape[1]
	inter_points[:,1] = inter_points[:,1] * 2 / input_shape[0] * original_shape[0]
	except:
	inter_points = []


	return new_segments, squares, score_array, inter_points