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[Add] Add rotate iou cpu evaluation on kitti dateset
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mmdet3d/evaluation/functional/kitti_utils/rotate_iou_cpu.py
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# Copyright (c) OpenMMLab. All rights reserved. | ||
##################### | ||
# Based on https://github.com/hongzhenwang/RRPN-revise | ||
# Licensed under The MIT License | ||
# Author: yanyan, scrin@foxmail.com | ||
##################### | ||
import math | ||
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import numpy as np | ||
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def div_up(m, n): | ||
return m // n + (m % n > 0) | ||
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def trangle_area(a, b, c): | ||
return ((a[0] - c[0]) * (b[1] - c[1]) - (a[1] - c[1]) * | ||
(b[0] - c[0])) / 2.0 | ||
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def area(int_pts, num_of_inter): | ||
area_val = 0.0 | ||
for i in range(num_of_inter - 2): | ||
area_val += abs( | ||
trangle_area(int_pts[:2], int_pts[2 * i + 2:2 * i + 4], | ||
int_pts[2 * i + 4:2 * i + 6])) | ||
return area_val | ||
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def sort_vertex_in_convex_polygon(int_pts, num_of_inter): | ||
if num_of_inter > 0: | ||
center = np.zeros((2, ), dtype=np.float32) | ||
center[:] = 0.0 | ||
for i in range(num_of_inter): | ||
center[0] += int_pts[2 * i] | ||
center[1] += int_pts[2 * i + 1] | ||
center[0] /= num_of_inter | ||
center[1] /= num_of_inter | ||
v = np.zeros((2, ), dtype=np.float32) | ||
vs = np.zeros((16, ), dtype=np.float32) | ||
for i in range(num_of_inter): | ||
v[0] = int_pts[2 * i] - center[0] | ||
v[1] = int_pts[2 * i + 1] - center[1] | ||
d = math.sqrt(v[0] * v[0] + v[1] * v[1]) | ||
v[0] = v[0] / d | ||
v[1] = v[1] / d | ||
if v[1] < 0: | ||
v[0] = -2 - v[0] | ||
vs[i] = v[0] | ||
j = 0 | ||
temp = 0 | ||
for i in range(1, num_of_inter): | ||
if vs[i - 1] > vs[i]: | ||
temp = vs[i] | ||
tx = int_pts[2 * i] | ||
ty = int_pts[2 * i + 1] | ||
j = i | ||
while j > 0 and vs[j - 1] > temp: | ||
vs[j] = vs[j - 1] | ||
int_pts[j * 2] = int_pts[j * 2 - 2] | ||
int_pts[j * 2 + 1] = int_pts[j * 2 - 1] | ||
j -= 1 | ||
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vs[j] = temp | ||
int_pts[j * 2] = tx | ||
int_pts[j * 2 + 1] = ty | ||
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def line_segment_intersection(pts1, pts2, i, j, temp_pts): | ||
A = np.zeros((2, ), dtype=np.float32) | ||
B = np.zeros((2, ), dtype=np.float32) | ||
C = np.zeros((2, ), dtype=np.float32) | ||
D = np.zeros((2, ), dtype=np.float32) | ||
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A[0] = pts1[2 * i] | ||
A[1] = pts1[2 * i + 1] | ||
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B[0] = pts1[2 * ((i + 1) % 4)] | ||
B[1] = pts1[2 * ((i + 1) % 4) + 1] | ||
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C[0] = pts2[2 * j] | ||
C[1] = pts2[2 * j + 1] | ||
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D[0] = pts2[2 * ((j + 1) % 4)] | ||
D[1] = pts2[2 * ((j + 1) % 4) + 1] | ||
BA0 = B[0] - A[0] | ||
BA1 = B[1] - A[1] | ||
DA0 = D[0] - A[0] | ||
CA0 = C[0] - A[0] | ||
DA1 = D[1] - A[1] | ||
CA1 = C[1] - A[1] | ||
acd = DA1 * CA0 > CA1 * DA0 | ||
bcd = (D[1] - B[1]) * (C[0] - B[0]) > (C[1] - B[1]) * (D[0] - B[0]) | ||
if acd != bcd: | ||
abc = CA1 * BA0 > BA1 * CA0 | ||
abd = DA1 * BA0 > BA1 * DA0 | ||
if abc != abd: | ||
DC0 = D[0] - C[0] | ||
DC1 = D[1] - C[1] | ||
ABBA = A[0] * B[1] - B[0] * A[1] | ||
CDDC = C[0] * D[1] - D[0] * C[1] | ||
DH = BA1 * DC0 - BA0 * DC1 | ||
Dx = ABBA * DC0 - BA0 * CDDC | ||
Dy = ABBA * DC1 - BA1 * CDDC | ||
temp_pts[0] = Dx / DH | ||
temp_pts[1] = Dy / DH | ||
return True | ||
return False | ||
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def line_segment_intersection_v1(pts1, pts2, i, j, temp_pts): | ||
a = np.zeros((2, ), dtype=np.float32) | ||
b = np.zeros((2, ), dtype=np.float32) | ||
c = np.zeros((2, ), dtype=np.float32) | ||
d = np.zeros((2, ), dtype=np.float32) | ||
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a[0] = pts1[2 * i] | ||
a[1] = pts1[2 * i + 1] | ||
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b[0] = pts1[2 * ((i + 1) % 4)] | ||
b[1] = pts1[2 * ((i + 1) % 4) + 1] | ||
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c[0] = pts2[2 * j] | ||
c[1] = pts2[2 * j + 1] | ||
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d[0] = pts2[2 * ((j + 1) % 4)] | ||
d[1] = pts2[2 * ((j + 1) % 4) + 1] | ||
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area_abc = trangle_area(a, b, c) | ||
area_abd = trangle_area(a, b, d) | ||
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if area_abc * area_abd >= 0: | ||
return False | ||
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area_cda = trangle_area(c, d, a) | ||
area_cdb = area_cda + area_abc - area_abd | ||
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if area_cda * area_cdb >= 0: | ||
return False | ||
t = area_cda / (area_abd - area_abc) | ||
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dx = t * (b[0] - a[0]) | ||
dy = t * (b[1] - a[1]) | ||
temp_pts[0] = a[0] + dx | ||
temp_pts[1] = a[1] + dy | ||
return True | ||
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def point_in_quadrilateral(pt_x, pt_y, corners): | ||
ab0 = corners[2] - corners[0] | ||
ab1 = corners[3] - corners[1] | ||
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ad0 = corners[6] - corners[0] | ||
ad1 = corners[7] - corners[1] | ||
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ap0 = pt_x - corners[0] | ||
ap1 = pt_y - corners[1] | ||
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abab = ab0 * ab0 + ab1 * ab1 | ||
abap = ab0 * ap0 + ab1 * ap1 | ||
adad = ad0 * ad0 + ad1 * ad1 | ||
adap = ad0 * ap0 + ad1 * ap1 | ||
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return abab >= abap and abap >= 0 and adad >= adap and adap >= 0 | ||
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def quadrilateral_intersection(pts1, pts2, int_pts): | ||
num_of_inter = 0 | ||
for i in range(4): | ||
if point_in_quadrilateral(pts1[2 * i], pts1[2 * i + 1], pts2): | ||
int_pts[num_of_inter * 2] = pts1[2 * i] | ||
int_pts[num_of_inter * 2 + 1] = pts1[2 * i + 1] | ||
num_of_inter += 1 | ||
if point_in_quadrilateral(pts2[2 * i], pts2[2 * i + 1], pts1): | ||
int_pts[num_of_inter * 2] = pts2[2 * i] | ||
int_pts[num_of_inter * 2 + 1] = pts2[2 * i + 1] | ||
num_of_inter += 1 | ||
temp_pts = np.zeros((2, ), dtype=np.float32) | ||
for i in range(4): | ||
for j in range(4): | ||
has_pts = line_segment_intersection(pts1, pts2, i, j, temp_pts) | ||
if has_pts: | ||
int_pts[num_of_inter * 2] = temp_pts[0] | ||
int_pts[num_of_inter * 2 + 1] = temp_pts[1] | ||
num_of_inter += 1 | ||
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return num_of_inter | ||
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def rbbox_to_corners(corners, rbbox): | ||
# generate clockwise corners and rotate it clockwise | ||
angle = rbbox[4] | ||
a_cos = math.cos(angle) | ||
a_sin = math.sin(angle) | ||
center_x = rbbox[0] | ||
center_y = rbbox[1] | ||
x_d = rbbox[2] | ||
y_d = rbbox[3] | ||
corners_x = np.zeros((4, ), dtype=np.float32) | ||
corners_y = np.zeros((4, ), dtype=np.float32) | ||
corners_x[0] = -x_d / 2 | ||
corners_x[1] = -x_d / 2 | ||
corners_x[2] = x_d / 2 | ||
corners_x[3] = x_d / 2 | ||
corners_y[0] = -y_d / 2 | ||
corners_y[1] = y_d / 2 | ||
corners_y[2] = y_d / 2 | ||
corners_y[3] = -y_d / 2 | ||
for i in range(4): | ||
corners[2 * i] = a_cos * corners_x[i] + a_sin * corners_y[i] + center_x | ||
corners[2 * i + | ||
1] = -a_sin * corners_x[i] + a_cos * corners_y[i] + center_y | ||
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def inter(rbbox1, rbbox2): | ||
corners1 = np.zeros((8, ), dtype=np.float32) | ||
corners2 = np.zeros((8, ), dtype=np.float32) | ||
intersection_corners = np.zeros((16, ), dtype=np.float32) | ||
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rbbox_to_corners(corners1, rbbox1) | ||
rbbox_to_corners(corners2, rbbox2) | ||
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num_intersection = quadrilateral_intersection(corners1, corners2, | ||
intersection_corners) | ||
sort_vertex_in_convex_polygon(intersection_corners, num_intersection) | ||
# print(intersection_corners.reshape([-1, 2])[:num_intersection]) | ||
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return area(intersection_corners, num_intersection) | ||
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def devRotateIoUEval(rbox1, rbox2, criterion=-1): | ||
area1 = rbox1[2] * rbox1[3] | ||
area2 = rbox2[2] * rbox2[3] | ||
area_inter = inter(rbox1, rbox2) | ||
if criterion == -1: | ||
return area_inter / (area1 + area2 - area_inter) | ||
elif criterion == 0: | ||
return area_inter / area1 | ||
elif criterion == 1: | ||
return area_inter / area2 | ||
else: | ||
return area_inter | ||
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def rotate_iou_cpu_eval(dev_boxes, dev_query_boxes, criterion=-1): | ||
num_boxes = dev_boxes.shape[0] | ||
num_qboxes = dev_query_boxes.shape[0] | ||
dev_iou = np.zeros((num_boxes, num_qboxes)) | ||
for box_i in range(num_boxes): | ||
for qbox_i in range(num_qboxes): | ||
dev_iou[box_i, | ||
qbox_i] = devRotateIoUEval(dev_query_boxes[qbox_i], | ||
dev_boxes[box_i], criterion) | ||
return dev_iou |