# Copyright (c) 2019 PaddlePaddle Authors. All Rights Reserved. # # 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. from __future__ import absolute_import from __future__ import division from __future__ import print_function try: from collections.abc import Sequence except Exception: from collections import Sequence import logging import cv2 import numpy as np from scipy import ndimage from .operators import register_op, BaseOperator from .op_helper import jaccard_overlap, gaussian2D logger = logging.getLogger(__name__) __all__ = [ 'PadBatch', 'RandomShape', 'PadMultiScaleTest', 'Gt2YoloTarget', 'Gt2FCOSTarget', 'Gt2TTFTarget', 'Gt2Solov2Target', ] @register_op class PadBatch(BaseOperator): """ Pad a batch of samples so they can be divisible by a stride. The layout of each image should be 'CHW'. Args: pad_to_stride (int): If `pad_to_stride > 0`, pad zeros to ensure height and width is divisible by `pad_to_stride`. """ def __init__(self, pad_to_stride=0, use_padded_im_info=True): super(PadBatch, self).__init__() self.pad_to_stride = pad_to_stride self.use_padded_im_info = use_padded_im_info def __call__(self, samples, context=None): """ Args: samples (list): a batch of sample, each is dict. """ coarsest_stride = self.pad_to_stride if coarsest_stride == 0: return samples max_shape = np.array([data['image'].shape for data in samples]).max( axis=0) if coarsest_stride > 0: max_shape[1] = int( np.ceil(max_shape[1] / coarsest_stride) * coarsest_stride) max_shape[2] = int( np.ceil(max_shape[2] / coarsest_stride) * coarsest_stride) padding_batch = [] for data in samples: im = data['image'] im_c, im_h, im_w = im.shape[:] padding_im = np.zeros( (im_c, max_shape[1], max_shape[2]), dtype=np.float32) padding_im[:, :im_h, :im_w] = im data['image'] = padding_im if self.use_padded_im_info: data['im_info'][:2] = max_shape[1:3] if 'semantic' in data.keys() and data['semantic'] is not None: semantic = data['semantic'] padding_sem = np.zeros( (1, max_shape[1], max_shape[2]), dtype=np.float32) padding_sem[:, :im_h, :im_w] = semantic data['semantic'] = padding_sem if 'gt_segm' in data.keys() and data['gt_segm'] is not None: gt_segm = data['gt_segm'] padding_segm = np.zeros( (gt_segm.shape[0], max_shape[1], max_shape[2]), dtype=np.uint8) padding_segm[:, :im_h, :im_w] = gt_segm data['gt_segm'] = padding_segm return samples @register_op class RandomShape(BaseOperator): """ Randomly reshape a batch. If random_inter is True, also randomly select one an interpolation algorithm [cv2.INTER_NEAREST, cv2.INTER_LINEAR, cv2.INTER_AREA, cv2.INTER_CUBIC, cv2.INTER_LANCZOS4]. If random_inter is False, use cv2.INTER_NEAREST. Args: sizes (list): list of int, random choose a size from these random_inter (bool): whether to randomly interpolation, defalut true. """ def __init__(self, sizes=[], random_inter=False, resize_box=False): super(RandomShape, self).__init__() self.sizes = sizes self.random_inter = random_inter self.interps = [ cv2.INTER_NEAREST, cv2.INTER_LINEAR, cv2.INTER_AREA, cv2.INTER_CUBIC, cv2.INTER_LANCZOS4, ] if random_inter else [] self.resize_box = resize_box def __call__(self, samples, context=None): shape = np.random.choice(self.sizes) method = np.random.choice(self.interps) if self.random_inter \ else cv2.INTER_NEAREST for i in range(len(samples)): im = samples[i]['image'] h, w = im.shape[:2] scale_x = float(shape) / w scale_y = float(shape) / h im = cv2.resize( im, None, None, fx=scale_x, fy=scale_y, interpolation=method) samples[i]['image'] = im if self.resize_box and 'gt_bbox' in samples[i] and len(samples[0][ 'gt_bbox']) > 0: scale_array = np.array([scale_x, scale_y] * 2, dtype=np.float32) samples[i]['gt_bbox'] = np.clip(samples[i]['gt_bbox'] * scale_array, 0, float(shape) - 1) return samples @register_op class PadMultiScaleTest(BaseOperator): """ Pad the image so they can be divisible by a stride for multi-scale testing. Args: pad_to_stride (int): If `pad_to_stride > 0`, pad zeros to ensure height and width is divisible by `pad_to_stride`. """ def __init__(self, pad_to_stride=0): super(PadMultiScaleTest, self).__init__() self.pad_to_stride = pad_to_stride def __call__(self, samples, context=None): coarsest_stride = self.pad_to_stride if coarsest_stride == 0: return samples batch_input = True if not isinstance(samples, Sequence): batch_input = False samples = [samples] if len(samples) != 1: raise ValueError("Batch size must be 1 when using multiscale test, " "but now batch size is {}".format(len(samples))) for i in range(len(samples)): sample = samples[i] for k in sample.keys(): # hard code if k.startswith('image'): im = sample[k] im_c, im_h, im_w = im.shape max_h = int( np.ceil(im_h / coarsest_stride) * coarsest_stride) max_w = int( np.ceil(im_w / coarsest_stride) * coarsest_stride) padding_im = np.zeros( (im_c, max_h, max_w), dtype=np.float32) padding_im[:, :im_h, :im_w] = im sample[k] = padding_im info_name = 'im_info' if k == 'image' else 'im_info_' + k # update im_info sample[info_name][:2] = [max_h, max_w] if not batch_input: samples = samples[0] return samples @register_op class Gt2YoloTarget(BaseOperator): """ Generate YOLOv3 targets by groud truth data, this operator is only used in fine grained YOLOv3 loss mode """ def __init__(self, anchors, anchor_masks, downsample_ratios, num_classes=80, iou_thresh=1.): super(Gt2YoloTarget, self).__init__() self.anchors = anchors self.anchor_masks = anchor_masks self.downsample_ratios = downsample_ratios self.num_classes = num_classes self.iou_thresh = iou_thresh def __call__(self, samples, context=None): assert len(self.anchor_masks) == len(self.downsample_ratios), \ "anchor_masks', and 'downsample_ratios' should have same length." h, w = samples[0]['image'].shape[1:3] an_hw = np.array(self.anchors) / np.array([[w, h]]) for sample in samples: # im, gt_bbox, gt_class, gt_score = sample im = sample['image'] gt_bbox = sample['gt_bbox'] gt_class = sample['gt_class'] gt_score = sample['gt_score'] for i, ( mask, downsample_ratio ) in enumerate(zip(self.anchor_masks, self.downsample_ratios)): grid_h = int(h / downsample_ratio) grid_w = int(w / downsample_ratio) target = np.zeros( (len(mask), 6 + self.num_classes, grid_h, grid_w), dtype=np.float32) for b in range(gt_bbox.shape[0]): gx, gy, gw, gh = gt_bbox[b, :] cls = gt_class[b] score = gt_score[b] if gw <= 0. or gh <= 0. or score <= 0.: continue # find best match anchor index best_iou = 0. best_idx = -1 for an_idx in range(an_hw.shape[0]): iou = jaccard_overlap( [0., 0., gw, gh], [0., 0., an_hw[an_idx, 0], an_hw[an_idx, 1]]) if iou > best_iou: best_iou = iou best_idx = an_idx gi = int(gx * grid_w) gj = int(gy * grid_h) # gtbox should be regresed in this layes if best match # anchor index in anchor mask of this layer if best_idx in mask: best_n = mask.index(best_idx) # x, y, w, h, scale target[best_n, 0, gj, gi] = gx * grid_w - gi target[best_n, 1, gj, gi] = gy * grid_h - gj target[best_n, 2, gj, gi] = np.log( gw * w / self.anchors[best_idx][0]) target[best_n, 3, gj, gi] = np.log( gh * h / self.anchors[best_idx][1]) target[best_n, 4, gj, gi] = 2.0 - gw * gh # objectness record gt_score target[best_n, 5, gj, gi] = score # classification target[best_n, 6 + cls, gj, gi] = 1. # For non-matched anchors, calculate the target if the iou # between anchor and gt is larger than iou_thresh if self.iou_thresh < 1: for idx, mask_i in enumerate(mask): if mask_i == best_idx: continue iou = jaccard_overlap( [0., 0., gw, gh], [0., 0., an_hw[mask_i, 0], an_hw[mask_i, 1]]) if iou > self.iou_thresh: # x, y, w, h, scale target[idx, 0, gj, gi] = gx * grid_w - gi target[idx, 1, gj, gi] = gy * grid_h - gj target[idx, 2, gj, gi] = np.log( gw * w / self.anchors[mask_i][0]) target[idx, 3, gj, gi] = np.log( gh * h / self.anchors[mask_i][1]) target[idx, 4, gj, gi] = 2.0 - gw * gh # objectness record gt_score target[idx, 5, gj, gi] = score # classification target[idx, 6 + cls, gj, gi] = 1. sample['target{}'.format(i)] = target return samples @register_op class Gt2FCOSTarget(BaseOperator): """ Generate FCOS targets by groud truth data """ def __init__(self, object_sizes_boundary, center_sampling_radius, downsample_ratios, norm_reg_targets=False): super(Gt2FCOSTarget, self).__init__() self.center_sampling_radius = center_sampling_radius self.downsample_ratios = downsample_ratios self.INF = np.inf self.object_sizes_boundary = [-1] + object_sizes_boundary + [self.INF] object_sizes_of_interest = [] for i in range(len(self.object_sizes_boundary) - 1): object_sizes_of_interest.append([ self.object_sizes_boundary[i], self.object_sizes_boundary[i + 1] ]) self.object_sizes_of_interest = object_sizes_of_interest self.norm_reg_targets = norm_reg_targets def _compute_points(self, w, h): """ compute the corresponding points in each feature map :param h: image height :param w: image width :return: points from all feature map """ locations = [] for stride in self.downsample_ratios: shift_x = np.arange(0, w, stride).astype(np.float32) shift_y = np.arange(0, h, stride).astype(np.float32) shift_x, shift_y = np.meshgrid(shift_x, shift_y) shift_x = shift_x.flatten() shift_y = shift_y.flatten() location = np.stack([shift_x, shift_y], axis=1) + stride // 2 locations.append(location) num_points_each_level = [len(location) for location in locations] locations = np.concatenate(locations, axis=0) return locations, num_points_each_level def _convert_xywh2xyxy(self, gt_bbox, w, h): """ convert the bounding box from style xywh to xyxy :param gt_bbox: bounding boxes normalized into [0, 1] :param w: image width :param h: image height :return: bounding boxes in xyxy style """ bboxes = gt_bbox.copy() bboxes[:, [0, 2]] = bboxes[:, [0, 2]] * w bboxes[:, [1, 3]] = bboxes[:, [1, 3]] * h bboxes[:, 2] = bboxes[:, 0] + bboxes[:, 2] bboxes[:, 3] = bboxes[:, 1] + bboxes[:, 3] return bboxes def _check_inside_boxes_limited(self, gt_bbox, xs, ys, num_points_each_level): """ check if points is within the clipped boxes :param gt_bbox: bounding boxes :param xs: horizontal coordinate of points :param ys: vertical coordinate of points :return: the mask of points is within gt_box or not """ bboxes = np.reshape( gt_bbox, newshape=[1, gt_bbox.shape[0], gt_bbox.shape[1]]) bboxes = np.tile(bboxes, reps=[xs.shape[0], 1, 1]) ct_x = (bboxes[:, :, 0] + bboxes[:, :, 2]) / 2 ct_y = (bboxes[:, :, 1] + bboxes[:, :, 3]) / 2 beg = 0 clipped_box = bboxes.copy() for lvl, stride in enumerate(self.downsample_ratios): end = beg + num_points_each_level[lvl] stride_exp = self.center_sampling_radius * stride clipped_box[beg:end, :, 0] = np.maximum( bboxes[beg:end, :, 0], ct_x[beg:end, :] - stride_exp) clipped_box[beg:end, :, 1] = np.maximum( bboxes[beg:end, :, 1], ct_y[beg:end, :] - stride_exp) clipped_box[beg:end, :, 2] = np.minimum( bboxes[beg:end, :, 2], ct_x[beg:end, :] + stride_exp) clipped_box[beg:end, :, 3] = np.minimum( bboxes[beg:end, :, 3], ct_y[beg:end, :] + stride_exp) beg = end l_res = xs - clipped_box[:, :, 0] r_res = clipped_box[:, :, 2] - xs t_res = ys - clipped_box[:, :, 1] b_res = clipped_box[:, :, 3] - ys clipped_box_reg_targets = np.stack([l_res, t_res, r_res, b_res], axis=2) inside_gt_box = np.min(clipped_box_reg_targets, axis=2) > 0 return inside_gt_box def __call__(self, samples, context=None): assert len(self.object_sizes_of_interest) == len(self.downsample_ratios), \ "object_sizes_of_interest', and 'downsample_ratios' should have same length." for sample in samples: # im, gt_bbox, gt_class, gt_score = sample im = sample['image'] im_info = sample['im_info'] bboxes = sample['gt_bbox'] gt_class = sample['gt_class'] gt_score = sample['gt_score'] bboxes[:, [0, 2]] = bboxes[:, [0, 2]] * np.floor(im_info[1]) / \ np.floor(im_info[1] / im_info[2]) bboxes[:, [1, 3]] = bboxes[:, [1, 3]] * np.floor(im_info[0]) / \ np.floor(im_info[0] / im_info[2]) # calculate the locations h, w = sample['image'].shape[1:3] points, num_points_each_level = self._compute_points(w, h) object_scale_exp = [] for i, num_pts in enumerate(num_points_each_level): object_scale_exp.append( np.tile( np.array([self.object_sizes_of_interest[i]]), reps=[num_pts, 1])) object_scale_exp = np.concatenate(object_scale_exp, axis=0) gt_area = (bboxes[:, 2] - bboxes[:, 0]) * ( bboxes[:, 3] - bboxes[:, 1]) xs, ys = points[:, 0], points[:, 1] xs = np.reshape(xs, newshape=[xs.shape[0], 1]) xs = np.tile(xs, reps=[1, bboxes.shape[0]]) ys = np.reshape(ys, newshape=[ys.shape[0], 1]) ys = np.tile(ys, reps=[1, bboxes.shape[0]]) l_res = xs - bboxes[:, 0] r_res = bboxes[:, 2] - xs t_res = ys - bboxes[:, 1] b_res = bboxes[:, 3] - ys reg_targets = np.stack([l_res, t_res, r_res, b_res], axis=2) if self.center_sampling_radius > 0: is_inside_box = self._check_inside_boxes_limited( bboxes, xs, ys, num_points_each_level) else: is_inside_box = np.min(reg_targets, axis=2) > 0 # check if the targets is inside the corresponding level max_reg_targets = np.max(reg_targets, axis=2) lower_bound = np.tile( np.expand_dims( object_scale_exp[:, 0], axis=1), reps=[1, max_reg_targets.shape[1]]) high_bound = np.tile( np.expand_dims( object_scale_exp[:, 1], axis=1), reps=[1, max_reg_targets.shape[1]]) is_match_current_level = \ (max_reg_targets > lower_bound) & \ (max_reg_targets < high_bound) points2gtarea = np.tile( np.expand_dims( gt_area, axis=0), reps=[xs.shape[0], 1]) points2gtarea[is_inside_box == 0] = self.INF points2gtarea[is_match_current_level == 0] = self.INF points2min_area = points2gtarea.min(axis=1) points2min_area_ind = points2gtarea.argmin(axis=1) labels = gt_class[points2min_area_ind] + 1 labels[points2min_area == self.INF] = 0 reg_targets = reg_targets[range(xs.shape[0]), points2min_area_ind] ctn_targets = np.sqrt((reg_targets[:, [0, 2]].min(axis=1) / \ reg_targets[:, [0, 2]].max(axis=1)) * \ (reg_targets[:, [1, 3]].min(axis=1) / \ reg_targets[:, [1, 3]].max(axis=1))).astype(np.float32) ctn_targets = np.reshape( ctn_targets, newshape=[ctn_targets.shape[0], 1]) ctn_targets[labels <= 0] = 0 pos_ind = np.nonzero(labels != 0) reg_targets_pos = reg_targets[pos_ind[0], :] split_sections = [] beg = 0 for lvl in range(len(num_points_each_level)): end = beg + num_points_each_level[lvl] split_sections.append(end) beg = end labels_by_level = np.split(labels, split_sections, axis=0) reg_targets_by_level = np.split(reg_targets, split_sections, axis=0) ctn_targets_by_level = np.split(ctn_targets, split_sections, axis=0) for lvl in range(len(self.downsample_ratios)): grid_w = int(np.ceil(w / self.downsample_ratios[lvl])) grid_h = int(np.ceil(h / self.downsample_ratios[lvl])) if self.norm_reg_targets: sample['reg_target{}'.format(lvl)] = \ np.reshape( reg_targets_by_level[lvl] / \ self.downsample_ratios[lvl], newshape=[grid_h, grid_w, 4]) else: sample['reg_target{}'.format(lvl)] = np.reshape( reg_targets_by_level[lvl], newshape=[grid_h, grid_w, 4]) sample['labels{}'.format(lvl)] = np.reshape( labels_by_level[lvl], newshape=[grid_h, grid_w, 1]) sample['centerness{}'.format(lvl)] = np.reshape( ctn_targets_by_level[lvl], newshape=[grid_h, grid_w, 1]) return samples @register_op class Gt2TTFTarget(BaseOperator): """ Gt2TTFTarget Generate TTFNet targets by ground truth data Args: num_classes(int): the number of classes. down_ratio(int): the down ratio from images to heatmap, 4 by default. alpha(float): the alpha parameter to generate gaussian target. 0.54 by default. """ def __init__(self, num_classes, down_ratio=4, alpha=0.54): super(Gt2TTFTarget, self).__init__() self.down_ratio = down_ratio self.num_classes = num_classes self.alpha = alpha def __call__(self, samples, context=None): output_size = samples[0]['image'].shape[1] feat_size = output_size // self.down_ratio for sample in samples: heatmap = np.zeros( (self.num_classes, feat_size, feat_size), dtype='float32') box_target = np.ones( (4, feat_size, feat_size), dtype='float32') * -1 reg_weight = np.zeros((1, feat_size, feat_size), dtype='float32') gt_bbox = sample['gt_bbox'] gt_class = sample['gt_class'] bbox_w = gt_bbox[:, 2] - gt_bbox[:, 0] + 1 bbox_h = gt_bbox[:, 3] - gt_bbox[:, 1] + 1 area = bbox_w * bbox_h boxes_areas_log = np.log(area) boxes_ind = np.argsort(boxes_areas_log, axis=0)[::-1] boxes_area_topk_log = boxes_areas_log[boxes_ind] gt_bbox = gt_bbox[boxes_ind] gt_class = gt_class[boxes_ind] feat_gt_bbox = gt_bbox / self.down_ratio feat_gt_bbox = np.clip(feat_gt_bbox, 0, feat_size - 1) feat_hs, feat_ws = (feat_gt_bbox[:, 3] - feat_gt_bbox[:, 1], feat_gt_bbox[:, 2] - feat_gt_bbox[:, 0]) ct_inds = np.stack( [(gt_bbox[:, 0] + gt_bbox[:, 2]) / 2, (gt_bbox[:, 1] + gt_bbox[:, 3]) / 2], axis=1) / self.down_ratio h_radiuses_alpha = (feat_hs / 2. * self.alpha).astype('int32') w_radiuses_alpha = (feat_ws / 2. * self.alpha).astype('int32') for k in range(len(gt_bbox)): cls_id = gt_class[k] fake_heatmap = np.zeros((feat_size, feat_size), dtype='float32') self.draw_truncate_gaussian(fake_heatmap, ct_inds[k], h_radiuses_alpha[k], w_radiuses_alpha[k]) heatmap[cls_id] = np.maximum(heatmap[cls_id], fake_heatmap) box_target_inds = fake_heatmap > 0 box_target[:, box_target_inds] = gt_bbox[k][:, None] local_heatmap = fake_heatmap[box_target_inds] ct_div = np.sum(local_heatmap) local_heatmap *= boxes_area_topk_log[k] reg_weight[0, box_target_inds] = local_heatmap / ct_div sample['ttf_heatmap'] = heatmap sample['ttf_box_target'] = box_target sample['ttf_reg_weight'] = reg_weight return samples def draw_truncate_gaussian(self, heatmap, center, h_radius, w_radius): h, w = 2 * h_radius + 1, 2 * w_radius + 1 sigma_x = w / 6 sigma_y = h / 6 gaussian = gaussian2D((h, w), sigma_x, sigma_y) x, y = int(center[0]), int(center[1]) height, width = heatmap.shape[0:2] left, right = min(x, w_radius), min(width - x, w_radius + 1) top, bottom = min(y, h_radius), min(height - y, h_radius + 1) masked_heatmap = heatmap[y - top:y + bottom, x - left:x + right] masked_gaussian = gaussian[h_radius - top:h_radius + bottom, w_radius - left:w_radius + right] if min(masked_gaussian.shape) > 0 and min(masked_heatmap.shape) > 0: heatmap[y - top:y + bottom, x - left:x + right] = np.maximum( masked_heatmap, masked_gaussian) return heatmap @register_op class Gt2Solov2Target(BaseOperator): """Assign mask target and labels in SOLOv2 network. Args: num_grids (list): The list of feature map grids size. scale_ranges (list): The list of mask boundary range. coord_sigma (float): The coefficient of coordinate area length. sampling_ratio (float): The ratio of down sampling. """ def __init__(self, num_grids=[40, 36, 24, 16, 12], scale_ranges=[[1, 96], [48, 192], [96, 384], [192, 768], [384, 2048]], coord_sigma=0.2, sampling_ratio=4.0): super(Gt2Solov2Target, self).__init__() self.num_grids = num_grids self.scale_ranges = scale_ranges self.coord_sigma = coord_sigma self.sampling_ratio = sampling_ratio def _scale_size(self, im, scale): h, w = im.shape[:2] new_size = (int(w * float(scale) + 0.5), int(h * float(scale) + 0.5)) resized_img = cv2.resize( im, None, None, fx=scale, fy=scale, interpolation=cv2.INTER_LINEAR) return resized_img def __call__(self, samples, context=None): for sample in samples: gt_bboxes_raw = sample['gt_bbox'] gt_labels_raw = sample['gt_class'] im_c, im_h, im_w = sample['image'].shape[:] gt_masks_raw = sample['gt_segm'].astype(np.uint8) mask_feat_size = [ int(im_h / self.sampling_ratio), int(im_w / self.sampling_ratio) ] gt_areas = np.sqrt((gt_bboxes_raw[:, 2] - gt_bboxes_raw[:, 0]) * (gt_bboxes_raw[:, 3] - gt_bboxes_raw[:, 1])) ins_ind_label_list = [] grid_offset = [] idx = 0 for (lower_bound, upper_bound), num_grid \ in zip(self.scale_ranges, self.num_grids): hit_indices = ((gt_areas >= lower_bound) & (gt_areas <= upper_bound)).nonzero()[0] num_ins = len(hit_indices) ins_label = [] grid_order = [] cate_label = np.zeros([num_grid, num_grid], dtype=np.int64) ins_ind_label = np.zeros([num_grid**2], dtype=np.bool) if num_ins == 0: ins_label = np.zeros( [1, mask_feat_size[0], mask_feat_size[1]], dtype=np.uint8) ins_ind_label_list.append(ins_ind_label) sample['cate_label{}'.format(idx)] = cate_label.flatten() sample['ins_label{}'.format(idx)] = ins_label sample['grid_order{}'.format(idx)] = np.asarray([0]) grid_offset.append(1) idx += 1 continue gt_bboxes = gt_bboxes_raw[hit_indices] gt_labels = gt_labels_raw[hit_indices] gt_masks = gt_masks_raw[hit_indices, ...] half_ws = 0.5 * ( gt_bboxes[:, 2] - gt_bboxes[:, 0]) * self.coord_sigma half_hs = 0.5 * ( gt_bboxes[:, 3] - gt_bboxes[:, 1]) * self.coord_sigma for seg_mask, gt_label, half_h, half_w in zip( gt_masks, gt_labels, half_hs, half_ws): if seg_mask.sum() == 0: continue # mass center upsampled_size = (mask_feat_size[0] * 4, mask_feat_size[1] * 4) center_h, center_w = ndimage.measurements.center_of_mass( seg_mask) coord_w = int( (center_w / upsampled_size[1]) // (1. / num_grid)) coord_h = int( (center_h / upsampled_size[0]) // (1. / num_grid)) # left, top, right, down top_box = max(0, int(((center_h - half_h) / upsampled_size[0]) // (1. / num_grid))) down_box = min(num_grid - 1, int(((center_h + half_h) / upsampled_size[0]) // (1. / num_grid))) left_box = max(0, int(((center_w - half_w) / upsampled_size[1]) // (1. / num_grid))) right_box = min(num_grid - 1, int(((center_w + half_w) / upsampled_size[1]) // (1. / num_grid))) top = max(top_box, coord_h - 1) down = min(down_box, coord_h + 1) left = max(coord_w - 1, left_box) right = min(right_box, coord_w + 1) cate_label[top:(down + 1), left:(right + 1)] = gt_label seg_mask = self._scale_size( seg_mask, scale=1. / self.sampling_ratio) for i in range(top, down + 1): for j in range(left, right + 1): label = int(i * num_grid + j) cur_ins_label = np.zeros( [mask_feat_size[0], mask_feat_size[1]], dtype=np.uint8) cur_ins_label[:seg_mask.shape[0], :seg_mask.shape[ 1]] = seg_mask ins_label.append(cur_ins_label) ins_ind_label[label] = True grid_order.append(label) if ins_label == []: ins_label = np.zeros( [1, mask_feat_size[0], mask_feat_size[1]], dtype=np.uint8) ins_ind_label_list.append(ins_ind_label) sample['cate_label{}'.format(idx)] = cate_label.flatten() sample['ins_label{}'.format(idx)] = ins_label sample['grid_order{}'.format(idx)] = np.asarray([0]) grid_offset.append(1) else: ins_label = np.stack(ins_label, axis=0) ins_ind_label_list.append(ins_ind_label) sample['cate_label{}'.format(idx)] = cate_label.flatten() sample['ins_label{}'.format(idx)] = ins_label sample['grid_order{}'.format(idx)] = np.asarray(grid_order) assert len(grid_order) > 0 grid_offset.append(len(grid_order)) idx += 1 ins_ind_labels = np.concatenate([ ins_ind_labels_level_img for ins_ind_labels_level_img in ins_ind_label_list ]) fg_num = np.sum(ins_ind_labels) sample['fg_num'] = fg_num sample['grid_offset'] = np.asarray(grid_offset).astype(np.int32) return samples