# 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. import sys import paddle from ppdet.core.workspace import register, serializable from .target import rpn_anchor_target, generate_proposal_target, generate_mask_target, libra_generate_proposal_target import numpy as np @register @serializable class RPNTargetAssign(object): """ RPN targets assignment module The assignment consists of three steps: 1. Match anchor and ground-truth box, label the anchor with foreground or background sample 2. Sample anchors to keep the properly ratio between foreground and background 3. Generate the targets for classification and regression branch Args: batch_size_per_im (int): Total number of RPN samples per image. default 256 fg_fraction (float): Fraction of anchors that is labeled foreground, default 0.5 positive_overlap (float): Minimum overlap required between an anchor and ground-truth box for the (anchor, gt box) pair to be a foreground sample. default 0.7 negative_overlap (float): Maximum overlap allowed between an anchor and ground-truth box for the (anchor, gt box) pair to be a background sample. default 0.3 ignore_thresh(float): Threshold for ignoring the is_crowd ground-truth if the value is larger than zero. use_random (bool): Use random sampling to choose foreground and background boxes, default true. """ def __init__(self, batch_size_per_im=256, fg_fraction=0.5, positive_overlap=0.7, negative_overlap=0.3, ignore_thresh=-1., use_random=True): super(RPNTargetAssign, self).__init__() self.batch_size_per_im = batch_size_per_im self.fg_fraction = fg_fraction self.positive_overlap = positive_overlap self.negative_overlap = negative_overlap self.ignore_thresh = ignore_thresh self.use_random = use_random def __call__(self, inputs, anchors): """ inputs: ground-truth instances. anchor_box (Tensor): [num_anchors, 4], num_anchors are all anchors in all feature maps. """ gt_boxes = inputs['gt_bbox'] is_crowd = inputs.get('is_crowd', None) batch_size = len(gt_boxes) tgt_labels, tgt_bboxes, tgt_deltas = rpn_anchor_target( anchors, gt_boxes, self.batch_size_per_im, self.positive_overlap, self.negative_overlap, self.fg_fraction, self.use_random, batch_size, self.ignore_thresh, is_crowd) norm = self.batch_size_per_im * batch_size return tgt_labels, tgt_bboxes, tgt_deltas, norm @register class BBoxAssigner(object): __shared__ = ['num_classes'] """ RCNN targets assignment module The assignment consists of three steps: 1. Match RoIs and ground-truth box, label the RoIs with foreground or background sample 2. Sample anchors to keep the properly ratio between foreground and background 3. Generate the targets for classification and regression branch Args: batch_size_per_im (int): Total number of RoIs per image. default 512 fg_fraction (float): Fraction of RoIs that is labeled foreground, default 0.25 fg_thresh (float): Minimum overlap required between a RoI and ground-truth box for the (roi, gt box) pair to be a foreground sample. default 0.5 bg_thresh (float): Maximum overlap allowed between a RoI and ground-truth box for the (roi, gt box) pair to be a background sample. default 0.5 ignore_thresh(float): Threshold for ignoring the is_crowd ground-truth if the value is larger than zero. use_random (bool): Use random sampling to choose foreground and background boxes, default true cascade_iou (list[iou]): The list of overlap to select foreground and background of each stage, which is only used In Cascade RCNN. num_classes (int): The number of class. """ def __init__(self, batch_size_per_im=512, fg_fraction=.25, fg_thresh=.5, bg_thresh=.5, ignore_thresh=-1., use_random=True, cascade_iou=[0.5, 0.6, 0.7], num_classes=80): super(BBoxAssigner, self).__init__() self.batch_size_per_im = batch_size_per_im self.fg_fraction = fg_fraction self.fg_thresh = fg_thresh self.bg_thresh = bg_thresh self.ignore_thresh = ignore_thresh self.use_random = use_random self.cascade_iou = cascade_iou self.num_classes = num_classes def __call__(self, rpn_rois, rpn_rois_num, inputs, stage=0, is_cascade=False): gt_classes = inputs['gt_class'] gt_boxes = inputs['gt_bbox'] is_crowd = inputs.get('is_crowd', None) # rois, tgt_labels, tgt_bboxes, tgt_gt_inds # new_rois_num outs = generate_proposal_target( rpn_rois, gt_classes, gt_boxes, self.batch_size_per_im, self.fg_fraction, self.fg_thresh, self.bg_thresh, self.num_classes, self.ignore_thresh, is_crowd, self.use_random, is_cascade, self.cascade_iou[stage]) rois = outs[0] rois_num = outs[-1] # tgt_labels, tgt_bboxes, tgt_gt_inds targets = outs[1:4] return rois, rois_num, targets @register class BBoxLibraAssigner(object): __shared__ = ['num_classes'] """ Libra-RCNN targets assignment module The assignment consists of three steps: 1. Match RoIs and ground-truth box, label the RoIs with foreground or background sample 2. Sample anchors to keep the properly ratio between foreground and background 3. Generate the targets for classification and regression branch Args: batch_size_per_im (int): Total number of RoIs per image. default 512 fg_fraction (float): Fraction of RoIs that is labeled foreground, default 0.25 fg_thresh (float): Minimum overlap required between a RoI and ground-truth box for the (roi, gt box) pair to be a foreground sample. default 0.5 bg_thresh (float): Maximum overlap allowed between a RoI and ground-truth box for the (roi, gt box) pair to be a background sample. default 0.5 use_random (bool): Use random sampling to choose foreground and background boxes, default true cascade_iou (list[iou]): The list of overlap to select foreground and background of each stage, which is only used In Cascade RCNN. num_classes (int): The number of class. num_bins (int): The number of libra_sample. """ def __init__(self, batch_size_per_im=512, fg_fraction=.25, fg_thresh=.5, bg_thresh=.5, use_random=True, cascade_iou=[0.5, 0.6, 0.7], num_classes=80, num_bins=3): super(BBoxLibraAssigner, self).__init__() self.batch_size_per_im = batch_size_per_im self.fg_fraction = fg_fraction self.fg_thresh = fg_thresh self.bg_thresh = bg_thresh self.use_random = use_random self.cascade_iou = cascade_iou self.num_classes = num_classes self.num_bins = num_bins def __call__(self, rpn_rois, rpn_rois_num, inputs, stage=0, is_cascade=False): gt_classes = inputs['gt_class'] gt_boxes = inputs['gt_bbox'] # rois, tgt_labels, tgt_bboxes, tgt_gt_inds outs = libra_generate_proposal_target( rpn_rois, gt_classes, gt_boxes, self.batch_size_per_im, self.fg_fraction, self.fg_thresh, self.bg_thresh, self.num_classes, self.use_random, is_cascade, self.cascade_iou[stage], self.num_bins) rois = outs[0] rois_num = outs[-1] # tgt_labels, tgt_bboxes, tgt_gt_inds targets = outs[1:4] return rois, rois_num, targets @register @serializable class MaskAssigner(object): __shared__ = ['num_classes', 'mask_resolution'] """ Mask targets assignment module The assignment consists of three steps: 1. Select RoIs labels with foreground. 2. Encode the RoIs and corresponding gt polygons to generate mask target Args: num_classes (int): The number of class mask_resolution (int): The resolution of mask target, default 14 """ def __init__(self, num_classes=80, mask_resolution=14): super(MaskAssigner, self).__init__() self.num_classes = num_classes self.mask_resolution = mask_resolution def __call__(self, rois, tgt_labels, tgt_gt_inds, inputs): gt_segms = inputs['gt_poly'] outs = generate_mask_target(gt_segms, rois, tgt_labels, tgt_gt_inds, self.num_classes, self.mask_resolution) # mask_rois, mask_rois_num, tgt_classes, tgt_masks, mask_index, tgt_weights return outs @register class RBoxAssigner(object): """ assigner of rbox Args: pos_iou_thr (float): threshold of pos samples neg_iou_thr (float): threshold of neg samples min_iou_thr (float): the min threshold of samples ignore_iof_thr (int): the ignored threshold """ def __init__(self, pos_iou_thr=0.5, neg_iou_thr=0.4, min_iou_thr=0.0, ignore_iof_thr=-2): super(RBoxAssigner, self).__init__() self.pos_iou_thr = pos_iou_thr self.neg_iou_thr = neg_iou_thr self.min_iou_thr = min_iou_thr self.ignore_iof_thr = ignore_iof_thr def anchor_valid(self, anchors): """ Args: anchor: M x 4 Returns: """ if anchors.ndim == 3: anchors = anchors.reshape(-1, anchors.shape[-1]) assert anchors.ndim == 2 anchor_num = anchors.shape[0] anchor_valid = np.ones((anchor_num), np.uint8) anchor_inds = np.arange(anchor_num) return anchor_inds def rbox2delta(self, proposals, gt, means=[0, 0, 0, 0, 0], stds=[1, 1, 1, 1, 1]): """ Args: proposals: tensor [N, 5] gt: gt [N, 5] means: means [5] stds: stds [5] Returns: """ proposals = proposals.astype(np.float64) PI = np.pi gt_widths = gt[..., 2] gt_heights = gt[..., 3] gt_angle = gt[..., 4] proposals_widths = proposals[..., 2] proposals_heights = proposals[..., 3] proposals_angle = proposals[..., 4] coord = gt[..., 0:2] - proposals[..., 0:2] dx = (np.cos(proposals[..., 4]) * coord[..., 0] + np.sin(proposals[..., 4]) * coord[..., 1]) / proposals_widths dy = (-np.sin(proposals[..., 4]) * coord[..., 0] + np.cos(proposals[..., 4]) * coord[..., 1]) / proposals_heights dw = np.log(gt_widths / proposals_widths) dh = np.log(gt_heights / proposals_heights) da = (gt_angle - proposals_angle) da = (da + PI / 4) % PI - PI / 4 da /= PI deltas = np.stack([dx, dy, dw, dh, da], axis=-1) means = np.array(means, dtype=deltas.dtype) stds = np.array(stds, dtype=deltas.dtype) deltas = (deltas - means) / stds deltas = deltas.astype(np.float32) return deltas def assign_anchor(self, anchors, gt_bboxes, gt_lables, pos_iou_thr, neg_iou_thr, min_iou_thr=0.0, ignore_iof_thr=-2): """ Args: anchors: gt_bboxes:[M, 5] rc,yc,w,h,angle gt_lables: Returns: """ assert anchors.shape[1] == 4 or anchors.shape[1] == 5 assert gt_bboxes.shape[1] == 4 or gt_bboxes.shape[1] == 5 anchors_xc_yc = anchors gt_bboxes_xc_yc = gt_bboxes # calc rbox iou anchors_xc_yc = anchors_xc_yc.astype(np.float32) gt_bboxes_xc_yc = gt_bboxes_xc_yc.astype(np.float32) anchors_xc_yc = paddle.to_tensor(anchors_xc_yc, place=paddle.CPUPlace()) gt_bboxes_xc_yc = paddle.to_tensor( gt_bboxes_xc_yc, place=paddle.CPUPlace()) try: from rbox_iou_ops import rbox_iou except Exception as e: print("import custom_ops error, try install rbox_iou_ops " \ "following ppdet/ext_op/README.md", e) sys.stdout.flush() sys.exit(-1) iou = rbox_iou(gt_bboxes_xc_yc, anchors_xc_yc) iou = iou.numpy() iou = iou.T # every gt's anchor's index gt_bbox_anchor_inds = iou.argmax(axis=0) gt_bbox_anchor_iou = iou[gt_bbox_anchor_inds, np.arange(iou.shape[1])] gt_bbox_anchor_iou_inds = np.where(iou == gt_bbox_anchor_iou)[0] # every anchor's gt bbox's index anchor_gt_bbox_inds = iou.argmax(axis=1) anchor_gt_bbox_iou = iou[np.arange(iou.shape[0]), anchor_gt_bbox_inds] # (1) set labels=-2 as default labels = np.ones((iou.shape[0], ), dtype=np.int32) * ignore_iof_thr # (2) assign ignore labels[anchor_gt_bbox_iou < min_iou_thr] = ignore_iof_thr # (3) assign neg_ids -1 assign_neg_ids1 = anchor_gt_bbox_iou >= min_iou_thr assign_neg_ids2 = anchor_gt_bbox_iou < neg_iou_thr assign_neg_ids = np.logical_and(assign_neg_ids1, assign_neg_ids2) labels[assign_neg_ids] = -1 # anchor_gt_bbox_iou_inds # (4) assign max_iou as pos_ids >=0 anchor_gt_bbox_iou_inds = anchor_gt_bbox_inds[gt_bbox_anchor_iou_inds] # gt_bbox_anchor_iou_inds = np.logical_and(gt_bbox_anchor_iou_inds, anchor_gt_bbox_iou >= min_iou_thr) labels[gt_bbox_anchor_iou_inds] = gt_lables[anchor_gt_bbox_iou_inds] # (5) assign >= pos_iou_thr as pos_ids iou_pos_iou_thr_ids = anchor_gt_bbox_iou >= pos_iou_thr iou_pos_iou_thr_ids_box_inds = anchor_gt_bbox_inds[iou_pos_iou_thr_ids] labels[iou_pos_iou_thr_ids] = gt_lables[iou_pos_iou_thr_ids_box_inds] return anchor_gt_bbox_inds, anchor_gt_bbox_iou, labels def __call__(self, anchors, gt_bboxes, gt_labels, is_crowd): assert anchors.ndim == 2 assert anchors.shape[1] == 5 assert gt_bboxes.ndim == 2 assert gt_bboxes.shape[1] == 5 pos_iou_thr = self.pos_iou_thr neg_iou_thr = self.neg_iou_thr min_iou_thr = self.min_iou_thr ignore_iof_thr = self.ignore_iof_thr anchor_num = anchors.shape[0] anchors_inds = self.anchor_valid(anchors) anchors = anchors[anchors_inds] gt_bboxes = gt_bboxes is_crowd_slice = is_crowd not_crowd_inds = np.where(is_crowd_slice == 0) # Step1: match anchor and gt_bbox anchor_gt_bbox_inds, anchor_gt_bbox_iou, labels = self.assign_anchor( anchors, gt_bboxes, gt_labels.reshape(-1), pos_iou_thr, neg_iou_thr, min_iou_thr, ignore_iof_thr) # Step2: sample anchor pos_inds = np.where(labels >= 0)[0] neg_inds = np.where(labels == -1)[0] # Step3: make output anchors_num = anchors.shape[0] bbox_targets = np.zeros_like(anchors) bbox_weights = np.zeros_like(anchors) pos_labels = np.ones(anchors_num, dtype=np.int32) * -1 pos_labels_weights = np.zeros(anchors_num, dtype=np.float32) pos_sampled_anchors = anchors[pos_inds] #print('ancho target pos_inds', pos_inds, len(pos_inds)) pos_sampled_gt_boxes = gt_bboxes[anchor_gt_bbox_inds[pos_inds]] if len(pos_inds) > 0: pos_bbox_targets = self.rbox2delta(pos_sampled_anchors, pos_sampled_gt_boxes) bbox_targets[pos_inds, :] = pos_bbox_targets bbox_weights[pos_inds, :] = 1.0 pos_labels[pos_inds] = labels[pos_inds] pos_labels_weights[pos_inds] = 1.0 if len(neg_inds) > 0: pos_labels_weights[neg_inds] = 1.0 return (pos_labels, pos_labels_weights, bbox_targets, bbox_weights, pos_inds, neg_inds)