# copyright (c) 2022 PaddlePaddle Authors. All Rights Reserve.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import numpy as np
from shapely.geometry import Polygon
def points2polygon(points):
"""Convert k points to 1 polygon.
Args:
points (ndarray or list): A ndarray or a list of shape (2k)
that indicates k points.
Returns:
polygon (Polygon): A polygon object.
"""
if isinstance(points, list):
points = np.array(points)
assert isinstance(points, np.ndarray)
assert (points.size % 2 == 0) and (points.size >= 8)
point_mat = points.reshape([-1, 2])
return Polygon(point_mat)
def poly_intersection(poly_det, poly_gt, buffer=0.0001):
"""Calculate the intersection area between two polygon.
Args:
poly_det (Polygon): A polygon predicted by detector.
poly_gt (Polygon): A gt polygon.
Returns:
intersection_area (float): The intersection area between two polygons.
"""
assert isinstance(poly_det, Polygon)
assert isinstance(poly_gt, Polygon)
if buffer == 0:
poly_inter = poly_det & poly_gt
else:
poly_inter = poly_det.buffer(buffer) & poly_gt.buffer(buffer)
return poly_inter.area, poly_inter
def poly_union(poly_det, poly_gt):
"""Calculate the union area between two polygon.
Args:
poly_det (Polygon): A polygon predicted by detector.
poly_gt (Polygon): A gt polygon.
Returns:
union_area (float): The union area between two polygons.
"""
assert isinstance(poly_det, Polygon)
assert isinstance(poly_gt, Polygon)
area_det = poly_det.area
area_gt = poly_gt.area
area_inters, _ = poly_intersection(poly_det, poly_gt)
return area_det + area_gt - area_inters
def valid_boundary(x, with_score=True):
num = len(x)
if num < 8:
return False
if num % 2 == 0 and (not with_score):
return True
if num % 2 == 1 and with_score:
return True
return False
def boundary_iou(src, target):
"""Calculate the IOU between two boundaries.
Args:
src (list): Source boundary.
target (list): Target boundary.
Returns:
iou (float): The iou between two boundaries.
"""
assert valid_boundary(src, False)
assert valid_boundary(target, False)
src_poly = points2polygon(src)
target_poly = points2polygon(target)
return poly_iou(src_poly, target_poly)
def poly_iou(poly_det, poly_gt):
"""Calculate the IOU between two polygons.
Args:
poly_det (Polygon): A polygon predicted by detector.
poly_gt (Polygon): A gt polygon.
Returns:
iou (float): The IOU between two polygons.
"""
assert isinstance(poly_det, Polygon)
assert isinstance(poly_gt, Polygon)
area_inters, _ = poly_intersection(poly_det, poly_gt)
area_union = poly_union(poly_det, poly_gt)
if area_union == 0:
return 0.0
return area_inters / area_union
def poly_nms(polygons, threshold):
assert isinstance(polygons, list)
polygons = np.array(sorted(polygons, key=lambda x: x[-1]))
keep_poly = []
index = [i for i in range(polygons.shape[0])]
while len(index) > 0:
keep_poly.append(polygons[index[-1]].tolist())
A = polygons[index[-1]][:-1]
index = np.delete(index, -1)
iou_list = np.zeros((len(index), ))
for i in range(len(index)):
B = polygons[index[i]][:-1]
iou_list[i] = boundary_iou(A, B)
remove_index = np.where(iou_list > threshold)
index = np.delete(index, remove_index)
return keep_poly