# Copyright (c) 2020 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 paddle import paddle.nn as nn import paddle.nn.functional as F from paddle.nn.initializer import Normal, XavierUniform, KaimingNormal from paddle.regularizer import L2Decay from ppdet.core.workspace import register, create from ppdet.modeling import ops from .roi_extractor import RoIAlign from ..shape_spec import ShapeSpec from ..bbox_utils import bbox2delta from ppdet.modeling.layers import ConvNormLayer __all__ = ['TwoFCHead', 'XConvNormHead', 'BBoxHead'] @register class TwoFCHead(nn.Layer): def __init__(self, in_dim=256, mlp_dim=1024, resolution=7): super(TwoFCHead, self).__init__() self.in_dim = in_dim self.mlp_dim = mlp_dim fan = in_dim * resolution * resolution self.fc6 = nn.Linear( in_dim * resolution * resolution, mlp_dim, weight_attr=paddle.ParamAttr( initializer=XavierUniform(fan_out=fan))) self.fc7 = nn.Linear( mlp_dim, mlp_dim, weight_attr=paddle.ParamAttr(initializer=XavierUniform())) @classmethod def from_config(cls, cfg, input_shape): s = input_shape s = s[0] if isinstance(s, (list, tuple)) else s return {'in_dim': s.channels} @property def out_shape(self): return [ShapeSpec(channels=self.mlp_dim, )] def forward(self, rois_feat): rois_feat = paddle.flatten(rois_feat, start_axis=1, stop_axis=-1) fc6 = self.fc6(rois_feat) fc6 = F.relu(fc6) fc7 = self.fc7(fc6) fc7 = F.relu(fc7) return fc7 @register class XConvNormHead(nn.Layer): """ RCNN bbox head with serveral convolution layers Args: in_dim(int): num of channels for the input rois_feat num_convs(int): num of convolution layers for the rcnn bbox head conv_dim(int): num of channels for the conv layers mlp_dim(int): num of channels for the fc layers resolution(int): resolution of the rois_feat norm_type(str): norm type, 'gn' by defalut freeze_norm(bool): whether to freeze the norm stage_name(str): used in CascadeXConvNormHead, '' by default """ __shared__ = ['norm_type', 'freeze_norm'] def __init__(self, in_dim=256, num_convs=4, conv_dim=256, mlp_dim=1024, resolution=7, norm_type='gn', freeze_norm=False, stage_name=''): super(XConvNormHead, self).__init__() self.in_dim = in_dim self.num_convs = num_convs self.conv_dim = conv_dim self.mlp_dim = mlp_dim self.norm_type = norm_type self.freeze_norm = freeze_norm self.bbox_head_convs = [] fan = conv_dim * 3 * 3 initializer = KaimingNormal(fan_in=fan) for i in range(self.num_convs): in_c = in_dim if i == 0 else conv_dim head_conv_name = stage_name + 'bbox_head_conv{}'.format(i) head_conv = self.add_sublayer( head_conv_name, ConvNormLayer( ch_in=in_c, ch_out=conv_dim, filter_size=3, stride=1, norm_type=self.norm_type, norm_name=head_conv_name + '_norm', freeze_norm=self.freeze_norm, initializer=initializer, name=head_conv_name)) self.bbox_head_convs.append(head_conv) fan = conv_dim * resolution * resolution self.fc6 = nn.Linear( conv_dim * resolution * resolution, mlp_dim, weight_attr=paddle.ParamAttr( initializer=XavierUniform(fan_out=fan)), bias_attr=paddle.ParamAttr( learning_rate=2., regularizer=L2Decay(0.))) @classmethod def from_config(cls, cfg, input_shape): s = input_shape s = s[0] if isinstance(s, (list, tuple)) else s return {'in_dim': s.channels} @property def out_shape(self): return [ShapeSpec(channels=self.mlp_dim, )] def forward(self, rois_feat): for i in range(self.num_convs): rois_feat = F.relu(self.bbox_head_convs[i](rois_feat)) rois_feat = paddle.flatten(rois_feat, start_axis=1, stop_axis=-1) fc6 = F.relu(self.fc6(rois_feat)) return fc6 @register class BBoxHead(nn.Layer): __shared__ = ['num_classes'] __inject__ = ['bbox_assigner'] """ head (nn.Layer): Extract feature in bbox head in_channel (int): Input channel after RoI extractor roi_extractor (object): The module of RoI Extractor bbox_assigner (object): The module of Box Assigner, label and sample the box. with_pool (bool): Whether to use pooling for the RoI feature. num_classes (int): The number of classes bbox_weight (List[float]): The weight to get the decode box """ def __init__(self, head, in_channel, roi_extractor=RoIAlign().__dict__, bbox_assigner='BboxAssigner', with_pool=False, num_classes=80, bbox_weight=[10., 10., 5., 5.]): super(BBoxHead, self).__init__() self.head = head self.roi_extractor = roi_extractor if isinstance(roi_extractor, dict): self.roi_extractor = RoIAlign(**roi_extractor) self.bbox_assigner = bbox_assigner self.with_pool = with_pool self.num_classes = num_classes self.bbox_weight = bbox_weight self.bbox_score = nn.Linear( in_channel, self.num_classes + 1, weight_attr=paddle.ParamAttr(initializer=Normal( mean=0.0, std=0.01))) self.bbox_delta = nn.Linear( in_channel, 4 * self.num_classes, weight_attr=paddle.ParamAttr(initializer=Normal( mean=0.0, std=0.001))) self.assigned_label = None self.assigned_rois = None @classmethod def from_config(cls, cfg, input_shape): roi_pooler = cfg['roi_extractor'] assert isinstance(roi_pooler, dict) kwargs = RoIAlign.from_config(cfg, input_shape) roi_pooler.update(kwargs) kwargs = {'input_shape': input_shape} head = create(cfg['head'], **kwargs) return { 'roi_extractor': roi_pooler, 'head': head, 'in_channel': head.out_shape[0].channels } def forward(self, body_feats=None, rois=None, rois_num=None, inputs=None): """ body_feats (list[Tensor]): Feature maps from backbone rois (list[Tensor]): RoIs generated from RPN module rois_num (Tensor): The number of RoIs in each image inputs (dict{Tensor}): The ground-truth of image """ if self.training: rois, rois_num, targets = self.bbox_assigner(rois, rois_num, inputs) self.assigned_rois = (rois, rois_num) self.assigned_targets = targets rois_feat = self.roi_extractor(body_feats, rois, rois_num) bbox_feat = self.head(rois_feat) if self.with_pool: feat = F.adaptive_avg_pool2d(bbox_feat, output_size=1) feat = paddle.squeeze(feat, axis=[2, 3]) else: feat = bbox_feat scores = self.bbox_score(feat) deltas = self.bbox_delta(feat) if self.training: loss = self.get_loss(scores, deltas, targets, rois, self.bbox_weight) return loss, bbox_feat else: pred = self.get_prediction(scores, deltas) return pred, self.head def get_loss(self, scores, deltas, targets, rois, bbox_weight): """ scores (Tensor): scores from bbox head outputs deltas (Tensor): deltas from bbox head outputs targets (list[List[Tensor]]): bbox targets containing tgt_labels, tgt_bboxes and tgt_gt_inds rois (List[Tensor]): RoIs generated in each batch """ # TODO: better pass args tgt_labels, tgt_bboxes, tgt_gt_inds = targets tgt_labels = paddle.concat(tgt_labels) if len( tgt_labels) > 1 else tgt_labels[0] tgt_labels = tgt_labels.cast('int64') tgt_labels.stop_gradient = True loss_bbox_cls = F.cross_entropy( input=scores, label=tgt_labels, reduction='mean') # bbox reg cls_agnostic_bbox_reg = deltas.shape[1] == 4 fg_inds = paddle.nonzero( paddle.logical_and(tgt_labels >= 0, tgt_labels < self.num_classes)).flatten() cls_name = 'loss_bbox_cls' reg_name = 'loss_bbox_reg' loss_bbox = {} if cls_agnostic_bbox_reg: reg_delta = paddle.gather(deltas, fg_inds) else: fg_gt_classes = paddle.gather(tgt_labels, fg_inds) reg_row_inds = paddle.arange(fg_gt_classes.shape[0]).unsqueeze(1) reg_row_inds = paddle.tile(reg_row_inds, [1, 4]).reshape([-1, 1]) reg_col_inds = 4 * fg_gt_classes.unsqueeze(1) + paddle.arange(4) reg_col_inds = reg_col_inds.reshape([-1, 1]) reg_inds = paddle.concat([reg_row_inds, reg_col_inds], axis=1) reg_delta = paddle.gather(deltas, fg_inds) reg_delta = paddle.gather_nd(reg_delta, reg_inds).reshape([-1, 4]) rois = paddle.concat(rois) if len(rois) > 1 else rois[0] tgt_bboxes = paddle.concat(tgt_bboxes) if len( tgt_bboxes) > 1 else tgt_bboxes[0] reg_target = bbox2delta(rois, tgt_bboxes, bbox_weight) reg_target = paddle.gather(reg_target, fg_inds) reg_target.stop_gradient = True loss_bbox_reg = paddle.abs(reg_delta - reg_target).sum( ) / tgt_labels.shape[0] loss_bbox[cls_name] = loss_bbox_cls loss_bbox[reg_name] = loss_bbox_reg return loss_bbox def get_prediction(self, score, delta): bbox_prob = F.softmax(score) return delta, bbox_prob def get_head(self, ): return self.head def get_assigned_targets(self, ): return self.assigned_targets def get_assigned_rois(self, ): return self.assigned_rois