# 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 import paddle import paddle.nn as nn import paddle.nn.functional as F from ppdet.core.workspace import register from ..rbox_utils import rotated_iou_similarity, check_points_in_rotated_boxes from .utils import gather_topk_anchors, compute_max_iou_anchor __all__ = ['RotatedTaskAlignedAssigner'] @register class RotatedTaskAlignedAssigner(nn.Layer): """TOOD: Task-aligned One-stage Object Detection """ def __init__(self, topk=13, alpha=1.0, beta=6.0, eps=1e-9): super(RotatedTaskAlignedAssigner, self).__init__() self.topk = topk self.alpha = alpha self.beta = beta self.eps = eps @paddle.no_grad() def forward(self, pred_scores, pred_bboxes, anchor_points, num_anchors_list, gt_labels, gt_bboxes, pad_gt_mask, bg_index, gt_scores=None): r"""This code is based on https://github.com/fcjian/TOOD/blob/master/mmdet/core/bbox/assigners/task_aligned_assigner.py The assignment is done in following steps 1. compute alignment metric between all bbox (bbox of all pyramid levels) and gt 2. select top-k bbox as candidates for each gt 3. limit the positive sample's center in gt (because the anchor-free detector only can predict positive distance) 4. if an anchor box is assigned to multiple gts, the one with the highest iou will be selected. Args: pred_scores (Tensor, float32): predicted class probability, shape(B, L, C) pred_bboxes (Tensor, float32): predicted bounding boxes, shape(B, L, 5) anchor_points (Tensor, float32): pre-defined anchors, shape(1, L, 2), "cxcy" format num_anchors_list (List): num of anchors in each level, shape(L) gt_labels (Tensor, int64|int32): Label of gt_bboxes, shape(B, n, 1) gt_bboxes (Tensor, float32): Ground truth bboxes, shape(B, n, 5) pad_gt_mask (Tensor, float32): 1 means bbox, 0 means no bbox, shape(B, n, 1) bg_index (int): background index gt_scores (Tensor|None, float32) Score of gt_bboxes, shape(B, n, 1) Returns: assigned_labels (Tensor): (B, L) assigned_bboxes (Tensor): (B, L, 5) assigned_scores (Tensor): (B, L, C) """ assert pred_scores.ndim == pred_bboxes.ndim assert gt_labels.ndim == gt_bboxes.ndim and \ gt_bboxes.ndim == 3 batch_size, num_anchors, num_classes = pred_scores.shape _, num_max_boxes, _ = gt_bboxes.shape # negative batch if num_max_boxes == 0: assigned_labels = paddle.full( [batch_size, num_anchors], bg_index, dtype=gt_labels.dtype) assigned_bboxes = paddle.zeros([batch_size, num_anchors, 5]) assigned_scores = paddle.zeros( [batch_size, num_anchors, num_classes]) return assigned_labels, assigned_bboxes, assigned_scores # compute iou between gt and pred bbox, [B, n, L] ious = rotated_iou_similarity(gt_bboxes, pred_bboxes) ious = paddle.where(ious > 1 + self.eps, paddle.zeros_like(ious), ious) ious.stop_gradient = True # gather pred bboxes class score pred_scores = pred_scores.transpose([0, 2, 1]) batch_ind = paddle.arange( end=batch_size, dtype=gt_labels.dtype).unsqueeze(-1) gt_labels_ind = paddle.stack( [batch_ind.tile([1, num_max_boxes]), gt_labels.squeeze(-1)], axis=-1) bbox_cls_scores = paddle.gather_nd(pred_scores, gt_labels_ind) # compute alignment metrics, [B, n, L] alignment_metrics = bbox_cls_scores.pow(self.alpha) * ious.pow( self.beta) # check the positive sample's center in gt, [B, n, L] is_in_gts = check_points_in_rotated_boxes(anchor_points, gt_bboxes) # select topk largest alignment metrics pred bbox as candidates # for each gt, [B, n, L] is_in_topk = gather_topk_anchors( alignment_metrics * is_in_gts, self.topk, topk_mask=pad_gt_mask) # select positive sample, [B, n, L] mask_positive = is_in_topk * is_in_gts * pad_gt_mask # if an anchor box is assigned to multiple gts, # the one with the highest iou will be selected, [B, n, L] mask_positive_sum = mask_positive.sum(axis=-2) if mask_positive_sum.max() > 1: mask_multiple_gts = (mask_positive_sum.unsqueeze(1) > 1).tile( [1, num_max_boxes, 1]) is_max_iou = compute_max_iou_anchor(ious) mask_positive = paddle.where(mask_multiple_gts, is_max_iou, mask_positive) mask_positive_sum = mask_positive.sum(axis=-2) assigned_gt_index = mask_positive.argmax(axis=-2) # assigned target assigned_gt_index = assigned_gt_index + batch_ind * num_max_boxes assigned_labels = paddle.gather( gt_labels.flatten(), assigned_gt_index.flatten(), axis=0) assigned_labels = assigned_labels.reshape([batch_size, num_anchors]) assigned_labels = paddle.where( mask_positive_sum > 0, assigned_labels, paddle.full_like(assigned_labels, bg_index)) assigned_bboxes = paddle.gather( gt_bboxes.reshape([-1, 5]), assigned_gt_index.flatten(), axis=0) assigned_bboxes = assigned_bboxes.reshape([batch_size, num_anchors, 5]) assigned_scores = F.one_hot(assigned_labels, num_classes + 1) ind = list(range(num_classes + 1)) ind.remove(bg_index) assigned_scores = paddle.index_select( assigned_scores, paddle.to_tensor(ind), axis=-1) # rescale alignment metrics alignment_metrics *= mask_positive max_metrics_per_instance = alignment_metrics.max(axis=-1, keepdim=True) max_ious_per_instance = (ious * mask_positive).max(axis=-1, keepdim=True) alignment_metrics = alignment_metrics / ( max_metrics_per_instance + self.eps) * max_ious_per_instance alignment_metrics = alignment_metrics.max(-2).unsqueeze(-1) assigned_scores = assigned_scores * alignment_metrics assigned_bboxes.stop_gradient = True assigned_scores.stop_gradient = True assigned_labels.stop_gradient = True return assigned_labels, assigned_bboxes, assigned_scores