forked from PulseFocusPlatform/PulseFocusPlatform
392 lines
14 KiB
Python
392 lines
14 KiB
Python
# Copyright (c) 2021 PaddlePaddle Authors. All Rights Reserved.
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#
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# Licensed under the Apache License, Version 2.0 (the "License");
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# you may not use this file except in compliance with the License.
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# You may obtain a copy of the License at
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#
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# http://www.apache.org/licenses/LICENSE-2.0
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#
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# Unless required by applicable law or agreed to in writing, software
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# distributed under the License is distributed on an "AS IS" BASIS,
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# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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# See the License for the specific language governing permissions and
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# limitations under the License.
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from __future__ import absolute_import
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from __future__ import division
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from __future__ import print_function
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import os
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import cv2
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import numpy as np
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from collections import OrderedDict
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import paddle
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from ppdet.utils.logger import setup_logger
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logger = setup_logger(__name__)
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__all__ = ['face_eval_run', 'lmk2out']
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def face_eval_run(model,
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image_dir,
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gt_file,
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pred_dir='output/pred',
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eval_mode='widerface',
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multi_scale=False):
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# load ground truth files
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with open(gt_file, 'r') as f:
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gt_lines = f.readlines()
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imid2path = []
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pos_gt = 0
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while pos_gt < len(gt_lines):
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name_gt = gt_lines[pos_gt].strip('\n\t').split()[0]
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imid2path.append(name_gt)
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pos_gt += 1
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n_gt = int(gt_lines[pos_gt].strip('\n\t').split()[0])
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pos_gt += 1 + n_gt
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logger.info('The ground truth file load {} images'.format(len(imid2path)))
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dets_dist = OrderedDict()
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for iter_id, im_path in enumerate(imid2path):
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image_path = os.path.join(image_dir, im_path)
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if eval_mode == 'fddb':
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image_path += '.jpg'
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assert os.path.exists(image_path)
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image = cv2.imread(image_path)
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image = cv2.cvtColor(image, cv2.COLOR_BGR2RGB)
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if multi_scale:
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shrink, max_shrink = get_shrink(image.shape[0], image.shape[1])
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det0 = detect_face(model, image, shrink)
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det1 = flip_test(model, image, shrink)
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[det2, det3] = multi_scale_test(model, image, max_shrink)
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det4 = multi_scale_test_pyramid(model, image, max_shrink)
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det = np.row_stack((det0, det1, det2, det3, det4))
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dets = bbox_vote(det)
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else:
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dets = detect_face(model, image, 1)
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if eval_mode == 'widerface':
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save_widerface_bboxes(image_path, dets, pred_dir)
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else:
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dets_dist[im_path] = dets
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if iter_id % 100 == 0:
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logger.info('Test iter {}'.format(iter_id))
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if eval_mode == 'fddb':
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save_fddb_bboxes(dets_dist, pred_dir)
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logger.info("Finish evaluation.")
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def detect_face(model, image, shrink):
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image_shape = [image.shape[0], image.shape[1]]
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if shrink != 1:
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h, w = int(image_shape[0] * shrink), int(image_shape[1] * shrink)
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image = cv2.resize(image, (w, h))
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image_shape = [h, w]
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img = face_img_process(image)
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image_shape = np.asarray([image_shape])
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scale_factor = np.asarray([[shrink, shrink]])
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data = {
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"image": paddle.to_tensor(
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img, dtype='float32'),
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"im_shape": paddle.to_tensor(
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image_shape, dtype='float32'),
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"scale_factor": paddle.to_tensor(
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scale_factor, dtype='float32')
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}
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model.eval()
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detection = model(data)
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detection = detection['bbox'].numpy()
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# layout: xmin, ymin, xmax. ymax, score
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if np.prod(detection.shape) == 1:
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logger.info("No face detected")
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return np.array([[0, 0, 0, 0, 0]])
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det_conf = detection[:, 1]
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det_xmin = detection[:, 2]
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det_ymin = detection[:, 3]
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det_xmax = detection[:, 4]
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det_ymax = detection[:, 5]
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det = np.column_stack((det_xmin, det_ymin, det_xmax, det_ymax, det_conf))
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return det
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def flip_test(model, image, shrink):
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img = cv2.flip(image, 1)
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det_f = detect_face(model, img, shrink)
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det_t = np.zeros(det_f.shape)
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img_width = image.shape[1]
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det_t[:, 0] = img_width - det_f[:, 2]
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det_t[:, 1] = det_f[:, 1]
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det_t[:, 2] = img_width - det_f[:, 0]
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det_t[:, 3] = det_f[:, 3]
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det_t[:, 4] = det_f[:, 4]
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return det_t
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def multi_scale_test(model, image, max_shrink):
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# Shrink detecting is only used to detect big faces
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st = 0.5 if max_shrink >= 0.75 else 0.5 * max_shrink
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det_s = detect_face(model, image, st)
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index = np.where(
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np.maximum(det_s[:, 2] - det_s[:, 0] + 1, det_s[:, 3] - det_s[:, 1] + 1)
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> 30)[0]
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det_s = det_s[index, :]
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# Enlarge one times
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bt = min(2, max_shrink) if max_shrink > 1 else (st + max_shrink) / 2
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det_b = detect_face(model, image, bt)
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# Enlarge small image x times for small faces
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if max_shrink > 2:
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bt *= 2
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while bt < max_shrink:
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det_b = np.row_stack((det_b, detect_face(model, image, bt)))
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bt *= 2
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det_b = np.row_stack((det_b, detect_face(model, image, max_shrink)))
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# Enlarged images are only used to detect small faces.
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if bt > 1:
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index = np.where(
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np.minimum(det_b[:, 2] - det_b[:, 0] + 1,
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det_b[:, 3] - det_b[:, 1] + 1) < 100)[0]
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det_b = det_b[index, :]
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# Shrinked images are only used to detect big faces.
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else:
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index = np.where(
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np.maximum(det_b[:, 2] - det_b[:, 0] + 1,
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det_b[:, 3] - det_b[:, 1] + 1) > 30)[0]
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det_b = det_b[index, :]
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return det_s, det_b
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def multi_scale_test_pyramid(model, image, max_shrink):
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# Use image pyramids to detect faces
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det_b = detect_face(model, image, 0.25)
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index = np.where(
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np.maximum(det_b[:, 2] - det_b[:, 0] + 1, det_b[:, 3] - det_b[:, 1] + 1)
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> 30)[0]
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det_b = det_b[index, :]
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st = [0.75, 1.25, 1.5, 1.75]
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for i in range(len(st)):
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if st[i] <= max_shrink:
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det_temp = detect_face(model, image, st[i])
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# Enlarged images are only used to detect small faces.
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if st[i] > 1:
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index = np.where(
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np.minimum(det_temp[:, 2] - det_temp[:, 0] + 1,
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det_temp[:, 3] - det_temp[:, 1] + 1) < 100)[0]
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det_temp = det_temp[index, :]
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# Shrinked images are only used to detect big faces.
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else:
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index = np.where(
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np.maximum(det_temp[:, 2] - det_temp[:, 0] + 1,
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det_temp[:, 3] - det_temp[:, 1] + 1) > 30)[0]
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det_temp = det_temp[index, :]
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det_b = np.row_stack((det_b, det_temp))
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return det_b
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def to_chw(image):
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"""
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Transpose image from HWC to CHW.
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Args:
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image (np.array): an image with HWC layout.
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"""
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# HWC to CHW
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if len(image.shape) == 3:
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image = np.swapaxes(image, 1, 2)
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image = np.swapaxes(image, 1, 0)
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return image
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def face_img_process(image,
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mean=[104., 117., 123.],
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std=[127.502231, 127.502231, 127.502231]):
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img = np.array(image)
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img = to_chw(img)
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img = img.astype('float32')
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img -= np.array(mean)[:, np.newaxis, np.newaxis].astype('float32')
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img /= np.array(std)[:, np.newaxis, np.newaxis].astype('float32')
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img = [img]
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img = np.array(img)
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return img
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def get_shrink(height, width):
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"""
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Args:
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height (int): image height.
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width (int): image width.
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"""
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# avoid out of memory
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max_shrink_v1 = (0x7fffffff / 577.0 / (height * width))**0.5
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max_shrink_v2 = ((678 * 1024 * 2.0 * 2.0) / (height * width))**0.5
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def get_round(x, loc):
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str_x = str(x)
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if '.' in str_x:
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str_before, str_after = str_x.split('.')
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len_after = len(str_after)
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if len_after >= 3:
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str_final = str_before + '.' + str_after[0:loc]
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return float(str_final)
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else:
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return x
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max_shrink = get_round(min(max_shrink_v1, max_shrink_v2), 2) - 0.3
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if max_shrink >= 1.5 and max_shrink < 2:
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max_shrink = max_shrink - 0.1
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elif max_shrink >= 2 and max_shrink < 3:
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max_shrink = max_shrink - 0.2
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elif max_shrink >= 3 and max_shrink < 4:
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max_shrink = max_shrink - 0.3
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elif max_shrink >= 4 and max_shrink < 5:
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max_shrink = max_shrink - 0.4
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elif max_shrink >= 5:
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max_shrink = max_shrink - 0.5
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elif max_shrink <= 0.1:
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max_shrink = 0.1
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shrink = max_shrink if max_shrink < 1 else 1
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return shrink, max_shrink
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def bbox_vote(det):
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order = det[:, 4].ravel().argsort()[::-1]
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det = det[order, :]
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if det.shape[0] == 0:
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dets = np.array([[10, 10, 20, 20, 0.002]])
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det = np.empty(shape=[0, 5])
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while det.shape[0] > 0:
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# IOU
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area = (det[:, 2] - det[:, 0] + 1) * (det[:, 3] - det[:, 1] + 1)
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xx1 = np.maximum(det[0, 0], det[:, 0])
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yy1 = np.maximum(det[0, 1], det[:, 1])
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xx2 = np.minimum(det[0, 2], det[:, 2])
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yy2 = np.minimum(det[0, 3], det[:, 3])
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w = np.maximum(0.0, xx2 - xx1 + 1)
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h = np.maximum(0.0, yy2 - yy1 + 1)
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inter = w * h
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o = inter / (area[0] + area[:] - inter)
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# nms
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merge_index = np.where(o >= 0.3)[0]
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det_accu = det[merge_index, :]
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det = np.delete(det, merge_index, 0)
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if merge_index.shape[0] <= 1:
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if det.shape[0] == 0:
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try:
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dets = np.row_stack((dets, det_accu))
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except:
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dets = det_accu
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continue
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det_accu[:, 0:4] = det_accu[:, 0:4] * np.tile(det_accu[:, -1:], (1, 4))
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max_score = np.max(det_accu[:, 4])
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det_accu_sum = np.zeros((1, 5))
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det_accu_sum[:, 0:4] = np.sum(det_accu[:, 0:4],
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axis=0) / np.sum(det_accu[:, -1:])
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det_accu_sum[:, 4] = max_score
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try:
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dets = np.row_stack((dets, det_accu_sum))
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except:
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dets = det_accu_sum
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dets = dets[0:750, :]
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keep_index = np.where(dets[:, 4] >= 0.01)[0]
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dets = dets[keep_index, :]
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return dets
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def save_widerface_bboxes(image_path, bboxes_scores, output_dir):
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image_name = image_path.split('/')[-1]
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image_class = image_path.split('/')[-2]
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odir = os.path.join(output_dir, image_class)
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if not os.path.exists(odir):
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os.makedirs(odir)
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ofname = os.path.join(odir, '%s.txt' % (image_name[:-4]))
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f = open(ofname, 'w')
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f.write('{:s}\n'.format(image_class + '/' + image_name))
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f.write('{:d}\n'.format(bboxes_scores.shape[0]))
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for box_score in bboxes_scores:
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xmin, ymin, xmax, ymax, score = box_score
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f.write('{:.1f} {:.1f} {:.1f} {:.1f} {:.3f}\n'.format(xmin, ymin, (
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xmax - xmin + 1), (ymax - ymin + 1), score))
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f.close()
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logger.info("The predicted result is saved as {}".format(ofname))
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def save_fddb_bboxes(bboxes_scores,
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output_dir,
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output_fname='pred_fddb_res.txt'):
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if not os.path.exists(output_dir):
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os.makedirs(output_dir)
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predict_file = os.path.join(output_dir, output_fname)
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f = open(predict_file, 'w')
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for image_path, dets in bboxes_scores.iteritems():
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f.write('{:s}\n'.format(image_path))
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f.write('{:d}\n'.format(dets.shape[0]))
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for box_score in dets:
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xmin, ymin, xmax, ymax, score = box_score
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width, height = xmax - xmin, ymax - ymin
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f.write('{:.1f} {:.1f} {:.1f} {:.1f} {:.3f}\n'
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.format(xmin, ymin, width, height, score))
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logger.info("The predicted result is saved as {}".format(predict_file))
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return predict_file
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def lmk2out(results, is_bbox_normalized=False):
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"""
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Args:
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results: request a dict, should include: `landmark`, `im_id`,
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if is_bbox_normalized=True, also need `im_shape`.
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is_bbox_normalized: whether or not landmark is normalized.
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"""
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xywh_res = []
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for t in results:
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bboxes = t['bbox'][0]
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lengths = t['bbox'][1][0]
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im_ids = np.array(t['im_id'][0]).flatten()
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if bboxes.shape == (1, 1) or bboxes is None:
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continue
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face_index = t['face_index'][0]
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prior_box = t['prior_boxes'][0]
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predict_lmk = t['landmark'][0]
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prior = np.reshape(prior_box, (-1, 4))
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predictlmk = np.reshape(predict_lmk, (-1, 10))
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k = 0
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for a in range(len(lengths)):
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num = lengths[a]
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im_id = int(im_ids[a])
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for i in range(num):
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score = bboxes[k][1]
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theindex = face_index[i][0]
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me_prior = prior[theindex, :]
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lmk_pred = predictlmk[theindex, :]
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prior_w = me_prior[2] - me_prior[0]
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prior_h = me_prior[3] - me_prior[1]
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prior_w_center = (me_prior[2] + me_prior[0]) / 2
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prior_h_center = (me_prior[3] + me_prior[1]) / 2
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lmk_decode = np.zeros((10))
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for j in [0, 2, 4, 6, 8]:
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lmk_decode[j] = lmk_pred[j] * 0.1 * prior_w + prior_w_center
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for j in [1, 3, 5, 7, 9]:
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lmk_decode[j] = lmk_pred[j] * 0.1 * prior_h + prior_h_center
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im_shape = t['im_shape'][0][a].tolist()
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image_h, image_w = int(im_shape[0]), int(im_shape[1])
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if is_bbox_normalized:
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lmk_decode = lmk_decode * np.array([
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image_w, image_h, image_w, image_h, image_w, image_h,
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image_w, image_h, image_w, image_h
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])
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lmk_res = {
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'image_id': im_id,
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'landmark': lmk_decode,
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'score': score,
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}
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xywh_res.append(lmk_res)
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k += 1
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return xywh_res
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