# Copyright (c) 2021 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 from numbers import Integral import cv2 import copy import numpy as np import random import math from .operators import BaseOperator, register_op from .batch_operators import Gt2TTFTarget from ppdet.modeling.bbox_utils import bbox_iou_np_expand from ppdet.utils.logger import setup_logger logger = setup_logger(__name__) __all__ = [ 'RGBReverse', 'LetterBoxResize', 'MOTRandomAffine', 'Gt2JDETargetThres', 'Gt2JDETargetMax', 'Gt2FairMOTTarget' ] @register_op class RGBReverse(BaseOperator): """RGB to BGR, or BGR to RGB, sensitive to MOTRandomAffine """ def __init__(self): super(RGBReverse, self).__init__() def apply(self, sample, context=None): im = sample['image'] sample['image'] = np.ascontiguousarray(im[:, :, ::-1]) return sample @register_op class LetterBoxResize(BaseOperator): def __init__(self, target_size): """ Resize image to target size, convert normalized xywh to pixel xyxy format ([x_center, y_center, width, height] -> [x0, y0, x1, y1]). Args: target_size (int|list): image target size. """ super(LetterBoxResize, self).__init__() if not isinstance(target_size, (Integral, Sequence)): raise TypeError( "Type of target_size is invalid. Must be Integer or List or Tuple, now is {}". format(type(target_size))) if isinstance(target_size, Integral): target_size = [target_size, target_size] self.target_size = target_size def apply_image(self, img, height, width, color=(127.5, 127.5, 127.5)): # letterbox: resize a rectangular image to a padded rectangular shape = img.shape[:2] # [height, width] ratio_h = float(height) / shape[0] ratio_w = float(width) / shape[1] ratio = min(ratio_h, ratio_w) new_shape = (round(shape[1] * ratio), round(shape[0] * ratio)) # [width, height] padw = (width - new_shape[0]) / 2 padh = (height - new_shape[1]) / 2 top, bottom = round(padh - 0.1), round(padh + 0.1) left, right = round(padw - 0.1), round(padw + 0.1) img = cv2.resize( img, new_shape, interpolation=cv2.INTER_AREA) # resized, no border img = cv2.copyMakeBorder( img, top, bottom, left, right, cv2.BORDER_CONSTANT, value=color) # padded rectangular return img, ratio, padw, padh def apply_bbox(self, bbox0, h, w, ratio, padw, padh): bboxes = bbox0.copy() bboxes[:, 0] = ratio * w * (bbox0[:, 0] - bbox0[:, 2] / 2) + padw bboxes[:, 1] = ratio * h * (bbox0[:, 1] - bbox0[:, 3] / 2) + padh bboxes[:, 2] = ratio * w * (bbox0[:, 0] + bbox0[:, 2] / 2) + padw bboxes[:, 3] = ratio * h * (bbox0[:, 1] + bbox0[:, 3] / 2) + padh return bboxes def apply(self, sample, context=None): """ Resize the image numpy. """ im = sample['image'] h, w = sample['im_shape'] if not isinstance(im, np.ndarray): raise TypeError("{}: image type is not numpy.".format(self)) if len(im.shape) != 3: raise ImageError('{}: image is not 3-dimensional.'.format(self)) # apply image height, width = self.target_size img, ratio, padw, padh = self.apply_image( im, height=height, width=width) sample['image'] = img new_shape = (round(h * ratio), round(w * ratio)) sample['im_shape'] = np.asarray(new_shape, dtype=np.float32) sample['scale_factor'] = np.asarray([ratio, ratio], dtype=np.float32) # apply bbox if 'gt_bbox' in sample and len(sample['gt_bbox']) > 0: sample['gt_bbox'] = self.apply_bbox(sample['gt_bbox'], h, w, ratio, padw, padh) return sample @register_op class MOTRandomAffine(BaseOperator): """ Affine transform to image and coords to achieve the rotate, scale and shift effect for training image. Args: degrees (list[2]): the rotate range to apply, transform range is [min, max] translate (list[2]): the translate range to apply, ransform range is [min, max] scale (list[2]): the scale range to apply, transform range is [min, max] shear (list[2]): the shear range to apply, transform range is [min, max] borderValue (list[3]): value used in case of a constant border when appling the perspective transformation reject_outside (bool): reject warped bounding bboxes outside of image Returns: records(dict): contain the image and coords after tranformed """ def __init__(self, degrees=(-5, 5), translate=(0.10, 0.10), scale=(0.50, 1.20), shear=(-2, 2), borderValue=(127.5, 127.5, 127.5), reject_outside=True): super(MOTRandomAffine, self).__init__() self.degrees = degrees self.translate = translate self.scale = scale self.shear = shear self.borderValue = borderValue self.reject_outside = reject_outside def apply(self, sample, context=None): # https://medium.com/uruvideo/dataset-augmentation-with-random-homographies-a8f4b44830d4 border = 0 # width of added border (optional) img = sample['image'] height, width = img.shape[0], img.shape[1] # Rotation and Scale R = np.eye(3) a = random.random() * (self.degrees[1] - self.degrees[0] ) + self.degrees[0] s = random.random() * (self.scale[1] - self.scale[0]) + self.scale[0] R[:2] = cv2.getRotationMatrix2D( angle=a, center=(width / 2, height / 2), scale=s) # Translation T = np.eye(3) T[0, 2] = ( random.random() * 2 - 1 ) * self.translate[0] * height + border # x translation (pixels) T[1, 2] = ( random.random() * 2 - 1 ) * self.translate[1] * width + border # y translation (pixels) # Shear S = np.eye(3) S[0, 1] = math.tan((random.random() * (self.shear[1] - self.shear[0]) + self.shear[0]) * math.pi / 180) # x shear (deg) S[1, 0] = math.tan((random.random() * (self.shear[1] - self.shear[0]) + self.shear[0]) * math.pi / 180) # y shear (deg) M = S @T @R # Combined rotation matrix. ORDER IS IMPORTANT HERE!! imw = cv2.warpPerspective( img, M, dsize=(width, height), flags=cv2.INTER_LINEAR, borderValue=self.borderValue) # BGR order borderValue if 'gt_bbox' in sample and len(sample['gt_bbox']) > 0: targets = sample['gt_bbox'] n = targets.shape[0] points = targets.copy() area0 = (points[:, 2] - points[:, 0]) * ( points[:, 3] - points[:, 1]) # warp points xy = np.ones((n * 4, 3)) xy[:, :2] = points[:, [0, 1, 2, 3, 0, 3, 2, 1]].reshape( n * 4, 2) # x1y1, x2y2, x1y2, x2y1 xy = (xy @M.T)[:, :2].reshape(n, 8) # create new boxes x = xy[:, [0, 2, 4, 6]] y = xy[:, [1, 3, 5, 7]] xy = np.concatenate( (x.min(1), y.min(1), x.max(1), y.max(1))).reshape(4, n).T # apply angle-based reduction radians = a * math.pi / 180 reduction = max(abs(math.sin(radians)), abs(math.cos(radians)))**0.5 x = (xy[:, 2] + xy[:, 0]) / 2 y = (xy[:, 3] + xy[:, 1]) / 2 w = (xy[:, 2] - xy[:, 0]) * reduction h = (xy[:, 3] - xy[:, 1]) * reduction xy = np.concatenate( (x - w / 2, y - h / 2, x + w / 2, y + h / 2)).reshape(4, n).T # reject warped points outside of image if self.reject_outside: np.clip(xy[:, 0], 0, width, out=xy[:, 0]) np.clip(xy[:, 2], 0, width, out=xy[:, 2]) np.clip(xy[:, 1], 0, height, out=xy[:, 1]) np.clip(xy[:, 3], 0, height, out=xy[:, 3]) w = xy[:, 2] - xy[:, 0] h = xy[:, 3] - xy[:, 1] area = w * h ar = np.maximum(w / (h + 1e-16), h / (w + 1e-16)) i = (w > 4) & (h > 4) & (area / (area0 + 1e-16) > 0.1) & (ar < 10) if sum(i) > 0: sample['gt_bbox'] = xy[i].astype(sample['gt_bbox'].dtype) sample['gt_class'] = sample['gt_class'][i] if 'difficult' in sample: sample['difficult'] = sample['difficult'][i] if 'gt_ide' in sample: sample['gt_ide'] = sample['gt_ide'][i] if 'is_crowd' in sample: sample['is_crowd'] = sample['is_crowd'][i] sample['image'] = imw return sample else: return sample @register_op class Gt2JDETargetThres(BaseOperator): __shared__ = ['num_classes'] """ Generate JDE targets by groud truth data when training Args: anchors (list): anchors of JDE model anchor_masks (list): anchor_masks of JDE model downsample_ratios (list): downsample ratios of JDE model ide_thresh (float): thresh of identity, higher is groud truth fg_thresh (float): thresh of foreground, higher is foreground bg_thresh (float): thresh of background, lower is background num_classes (int): number of classes """ def __init__(self, anchors, anchor_masks, downsample_ratios, ide_thresh=0.5, fg_thresh=0.5, bg_thresh=0.4, num_classes=1): super(Gt2JDETargetThres, self).__init__() self.anchors = anchors self.anchor_masks = anchor_masks self.downsample_ratios = downsample_ratios self.ide_thresh = ide_thresh self.fg_thresh = fg_thresh self.bg_thresh = bg_thresh self.num_classes = num_classes def generate_anchor(self, nGh, nGw, anchor_hw): nA = len(anchor_hw) yy, xx = np.meshgrid(np.arange(nGh), np.arange(nGw)) mesh = np.stack([xx.T, yy.T], axis=0) # [2, nGh, nGw] mesh = np.repeat(mesh[None, :], nA, axis=0) # [nA, 2, nGh, nGw] anchor_offset_mesh = anchor_hw[:, :, None][:, :, :, None] anchor_offset_mesh = np.repeat(anchor_offset_mesh, nGh, axis=-2) anchor_offset_mesh = np.repeat(anchor_offset_mesh, nGw, axis=-1) anchor_mesh = np.concatenate( [mesh, anchor_offset_mesh], axis=1) # [nA, 4, nGh, nGw] return anchor_mesh def encode_delta(self, gt_box_list, fg_anchor_list): px, py, pw, ph = fg_anchor_list[:, 0], fg_anchor_list[:,1], \ fg_anchor_list[:, 2], fg_anchor_list[:,3] gx, gy, gw, gh = gt_box_list[:, 0], gt_box_list[:, 1], \ gt_box_list[:, 2], gt_box_list[:, 3] dx = (gx - px) / pw dy = (gy - py) / ph dw = np.log(gw / pw) dh = np.log(gh / ph) return np.stack([dx, dy, dw, dh], axis=1) def pad_box(self, sample, num_max): assert 'gt_bbox' in sample bbox = sample['gt_bbox'] gt_num = len(bbox) pad_bbox = np.zeros((num_max, 4), dtype=np.float32) if gt_num > 0: pad_bbox[:gt_num, :] = bbox[:gt_num, :] sample['gt_bbox'] = pad_bbox if 'gt_score' in sample: pad_score = np.zeros((num_max, ), dtype=np.float32) if gt_num > 0: pad_score[:gt_num] = sample['gt_score'][:gt_num, 0] sample['gt_score'] = pad_score if 'difficult' in sample: pad_diff = np.zeros((num_max, ), dtype=np.int32) if gt_num > 0: pad_diff[:gt_num] = sample['difficult'][:gt_num, 0] sample['difficult'] = pad_diff if 'is_crowd' in sample: pad_crowd = np.zeros((num_max, ), dtype=np.int32) if gt_num > 0: pad_crowd[:gt_num] = sample['is_crowd'][:gt_num, 0] sample['is_crowd'] = pad_crowd if 'gt_ide' in sample: pad_ide = np.zeros((num_max, ), dtype=np.int32) if gt_num > 0: pad_ide[:gt_num] = sample['gt_ide'][:gt_num, 0] sample['gt_ide'] = pad_ide return sample 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] num_max = 0 for sample in samples: num_max = max(num_max, len(sample['gt_bbox'])) for sample in samples: gt_bbox = sample['gt_bbox'] gt_ide = sample['gt_ide'] for i, (anchor_hw, downsample_ratio ) in enumerate(zip(self.anchors, self.downsample_ratios)): anchor_hw = np.array( anchor_hw, dtype=np.float32) / downsample_ratio nA = len(anchor_hw) nGh, nGw = int(h / downsample_ratio), int(w / downsample_ratio) tbox = np.zeros((nA, nGh, nGw, 4), dtype=np.float32) tconf = np.zeros((nA, nGh, nGw), dtype=np.float32) tid = -np.ones((nA, nGh, nGw, 1), dtype=np.float32) gxy, gwh = gt_bbox[:, 0:2].copy(), gt_bbox[:, 2:4].copy() gxy[:, 0] = gxy[:, 0] * nGw gxy[:, 1] = gxy[:, 1] * nGh gwh[:, 0] = gwh[:, 0] * nGw gwh[:, 1] = gwh[:, 1] * nGh gxy[:, 0] = np.clip(gxy[:, 0], 0, nGw - 1) gxy[:, 1] = np.clip(gxy[:, 1], 0, nGh - 1) tboxes = np.concatenate([gxy, gwh], axis=1) anchor_mesh = self.generate_anchor(nGh, nGw, anchor_hw) anchor_list = np.transpose(anchor_mesh, (0, 2, 3, 1)).reshape(-1, 4) iou_pdist = bbox_iou_np_expand( anchor_list, tboxes, x1y1x2y2=False) iou_max = np.max(iou_pdist, axis=1) max_gt_index = np.argmax(iou_pdist, axis=1) iou_map = iou_max.reshape(nA, nGh, nGw) gt_index_map = max_gt_index.reshape(nA, nGh, nGw) id_index = iou_map > self.ide_thresh fg_index = iou_map > self.fg_thresh bg_index = iou_map < self.bg_thresh ign_index = (iou_map < self.fg_thresh) * ( iou_map > self.bg_thresh) tconf[fg_index] = 1 tconf[bg_index] = 0 tconf[ign_index] = -1 gt_index = gt_index_map[fg_index] gt_box_list = tboxes[gt_index] gt_id_list = gt_ide[gt_index_map[id_index]] if np.sum(fg_index) > 0: tid[id_index] = gt_id_list fg_anchor_list = anchor_list.reshape(nA, nGh, nGw, 4)[fg_index] delta_target = self.encode_delta(gt_box_list, fg_anchor_list) tbox[fg_index] = delta_target sample['tbox{}'.format(i)] = tbox sample['tconf{}'.format(i)] = tconf sample['tide{}'.format(i)] = tid sample.pop('gt_class') sample = self.pad_box(sample, num_max) return samples @register_op class Gt2JDETargetMax(BaseOperator): __shared__ = ['num_classes'] """ Generate JDE targets by groud truth data when evaluating Args: anchors (list): anchors of JDE model anchor_masks (list): anchor_masks of JDE model downsample_ratios (list): downsample ratios of JDE model max_iou_thresh (float): iou thresh for high quality anchor num_classes (int): number of classes """ def __init__(self, anchors, anchor_masks, downsample_ratios, max_iou_thresh=0.60, num_classes=1): super(Gt2JDETargetMax, self).__init__() self.anchors = anchors self.anchor_masks = anchor_masks self.downsample_ratios = downsample_ratios self.max_iou_thresh = max_iou_thresh self.num_classes = num_classes 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] for sample in samples: gt_bbox = sample['gt_bbox'] gt_ide = sample['gt_ide'] for i, (anchor_hw, downsample_ratio ) in enumerate(zip(self.anchors, self.downsample_ratios)): anchor_hw = np.array( anchor_hw, dtype=np.float32) / downsample_ratio nA = len(anchor_hw) nGh, nGw = int(h / downsample_ratio), int(w / downsample_ratio) tbox = np.zeros((nA, nGh, nGw, 4), dtype=np.float32) tconf = np.zeros((nA, nGh, nGw), dtype=np.float32) tid = -np.ones((nA, nGh, nGw, 1), dtype=np.float32) gxy, gwh = gt_bbox[:, 0:2].copy(), gt_bbox[:, 2:4].copy() gxy[:, 0] = gxy[:, 0] * nGw gxy[:, 1] = gxy[:, 1] * nGh gwh[:, 0] = gwh[:, 0] * nGw gwh[:, 1] = gwh[:, 1] * nGh gi = np.clip(gxy[:, 0], 0, nGw - 1).astype(int) gj = np.clip(gxy[:, 1], 0, nGh - 1).astype(int) # iou of targets-anchors (using wh only) box1 = gwh box2 = anchor_hw[:, None, :] inter_area = np.minimum(box1, box2).prod(2) iou = inter_area / ( box1.prod(1) + box2.prod(2) - inter_area + 1e-16) # Select best iou_pred and anchor iou_best = iou.max(0) # best anchor [0-2] for each target a = np.argmax(iou, axis=0) # Select best unique target-anchor combinations iou_order = np.argsort(-iou_best) # best to worst # Unique anchor selection u = np.stack((gi, gj, a), 0)[:, iou_order] _, first_unique = np.unique(u, axis=1, return_index=True) mask = iou_order[first_unique] # best anchor must share significant commonality (iou) with target # TODO: examine arbitrary threshold idx = mask[iou_best[mask] > self.max_iou_thresh] if len(idx) > 0: a_i, gj_i, gi_i = a[idx], gj[idx], gi[idx] t_box = gt_bbox[idx] t_id = gt_ide[idx] if len(t_box.shape) == 1: t_box = t_box.reshape(1, 4) gxy, gwh = t_box[:, 0:2].copy(), t_box[:, 2:4].copy() gxy[:, 0] = gxy[:, 0] * nGw gxy[:, 1] = gxy[:, 1] * nGh gwh[:, 0] = gwh[:, 0] * nGw gwh[:, 1] = gwh[:, 1] * nGh # XY coordinates tbox[:, :, :, 0:2][a_i, gj_i, gi_i] = gxy - gxy.astype(int) # Width and height in yolo method tbox[:, :, :, 2:4][a_i, gj_i, gi_i] = np.log(gwh / anchor_hw[a_i]) tconf[a_i, gj_i, gi_i] = 1 tid[a_i, gj_i, gi_i] = t_id sample['tbox{}'.format(i)] = tbox sample['tconf{}'.format(i)] = tconf sample['tide{}'.format(i)] = tid class Gt2FairMOTTarget(Gt2TTFTarget): __shared__ = ['num_classes'] """ Generate FairMOT targets by ground truth data. Difference between Gt2FairMOTTarget and Gt2TTFTarget are: 1. the gaussian kernal radius to generate a heatmap. 2. the targets needed during traing. Args: num_classes(int): the number of classes. down_ratio(int): the down ratio from images to heatmap, 4 by default. max_objs(int): the maximum number of ground truth objects in a image, 500 by default. """ def __init__(self, num_classes=1, down_ratio=4, max_objs=500): super(Gt2TTFTarget, self).__init__() self.down_ratio = down_ratio self.num_classes = num_classes self.max_objs = max_objs def __call__(self, samples, context=None): for b_id, sample in enumerate(samples): output_h = sample['image'].shape[1] // self.down_ratio output_w = sample['image'].shape[2] // self.down_ratio heatmap = np.zeros( (self.num_classes, output_h, output_w), dtype='float32') bbox_size = np.zeros((self.max_objs, 4), dtype=np.float32) center_offset = np.zeros((self.max_objs, 2), dtype=np.float32) index = np.zeros((self.max_objs, ), dtype=np.int64) index_mask = np.zeros((self.max_objs, ), dtype=np.int32) reid = np.zeros((self.max_objs, ), dtype=np.int64) bbox_xys = np.zeros((self.max_objs, 4), dtype=np.float32) gt_bbox = sample['gt_bbox'] gt_class = sample['gt_class'] gt_ide = sample['gt_ide'] for k in range(len(gt_bbox)): cls_id = gt_class[k][0] bbox = gt_bbox[k] ide = gt_ide[k][0] bbox[[0, 2]] = bbox[[0, 2]] * output_w bbox[[1, 3]] = bbox[[1, 3]] * output_h bbox_amodal = copy.deepcopy(bbox) bbox_amodal[0] = bbox_amodal[0] - bbox_amodal[2] / 2. bbox_amodal[1] = bbox_amodal[1] - bbox_amodal[3] / 2. bbox_amodal[2] = bbox_amodal[0] + bbox_amodal[2] bbox_amodal[3] = bbox_amodal[1] + bbox_amodal[3] bbox[0] = np.clip(bbox[0], 0, output_w - 1) bbox[1] = np.clip(bbox[1], 0, output_h - 1) h = bbox[3] w = bbox[2] bbox_xy = copy.deepcopy(bbox) bbox_xy[0] = bbox_xy[0] - bbox_xy[2] / 2 bbox_xy[1] = bbox_xy[1] - bbox_xy[3] / 2 bbox_xy[2] = bbox_xy[0] + bbox_xy[2] bbox_xy[3] = bbox_xy[1] + bbox_xy[3] if h > 0 and w > 0: radius = self.gaussian_radius((math.ceil(h), math.ceil(w))) radius = max(0, int(radius)) ct = np.array([bbox[0], bbox[1]], dtype=np.float32) ct_int = ct.astype(np.int32) self.draw_truncate_gaussian(heatmap[cls_id], ct_int, radius, radius) bbox_size[k] = ct[0] - bbox_amodal[0], ct[1] - bbox_amodal[1], \ bbox_amodal[2] - ct[0], bbox_amodal[3] - ct[1] index[k] = ct_int[1] * output_w + ct_int[0] center_offset[k] = ct - ct_int index_mask[k] = 1 reid[k] = ide bbox_xys[k] = bbox_xy sample['heatmap'] = heatmap sample['index'] = index sample['offset'] = center_offset sample['size'] = bbox_size sample['index_mask'] = index_mask sample['reid'] = reid sample['bbox_xys'] = bbox_xys sample.pop('is_crowd', None) sample.pop('difficult', None) sample.pop('gt_class', None) sample.pop('gt_bbox', None) sample.pop('gt_score', None) sample.pop('gt_ide', None) return samples def gaussian_radius(self, det_size, min_overlap=0.7): height, width = det_size a1 = 1 b1 = (height + width) c1 = width * height * (1 - min_overlap) / (1 + min_overlap) sq1 = np.sqrt(b1**2 - 4 * a1 * c1) r1 = (b1 + sq1) / 2 a2 = 4 b2 = 2 * (height + width) c2 = (1 - min_overlap) * width * height sq2 = np.sqrt(b2**2 - 4 * a2 * c2) r2 = (b2 + sq2) / 2 a3 = 4 * min_overlap b3 = -2 * min_overlap * (height + width) c3 = (min_overlap - 1) * width * height sq3 = np.sqrt(b3**2 - 4 * a3 * c3) r3 = (b3 + sq3) / 2 return min(r1, r2, r3)