# 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 import paddle.fluid as fluid from paddle.fluid.param_attr import ParamAttr from paddle.fluid.initializer import Normal, Xavier from paddle.fluid.regularizer import L2Decay from paddle.fluid.initializer import MSRA from ppdet.modeling.ops import MultiClassNMS from ppdet.modeling.ops import ConvNorm from ppdet.core.workspace import register __all__ = ['CascadeBBoxHead'] @register class CascadeBBoxHead(object): """ Cascade RCNN bbox head Args: head (object): the head module instance nms (object): `MultiClassNMS` instance num_classes: number of output classes """ __inject__ = ['head', 'nms'] __shared__ = ['num_classes'] def __init__(self, head, nms=MultiClassNMS().__dict__, num_classes=81): super(CascadeBBoxHead, self).__init__() self.head = head self.nms = nms self.num_classes = num_classes if isinstance(nms, dict): self.nms = MultiClassNMS(**nms) def get_output(self, roi_feat, cls_agnostic_bbox_reg=2, wb_scalar=1.0, name=''): """ Get bbox head output. Args: roi_feat (Variable): RoI feature from RoIExtractor. cls_agnostic_bbox_reg(Int): BBox regressor are class agnostic. wb_scalar(Float): Weights and Bias's learning rate. name(String): Layer's name Returns: cls_score(Variable): cls score. bbox_pred(Variable): bbox regression. """ head_feat = self.head(roi_feat, wb_scalar, name) cls_score = fluid.layers.fc(input=head_feat, size=self.num_classes, act=None, name='cls_score' + name, param_attr=ParamAttr( name='cls_score%s_w' % name, initializer=Normal( loc=0.0, scale=0.01), learning_rate=wb_scalar), bias_attr=ParamAttr( name='cls_score%s_b' % name, learning_rate=wb_scalar * 2, regularizer=L2Decay(0.))) bbox_pred = fluid.layers.fc(input=head_feat, size=4 * cls_agnostic_bbox_reg, act=None, name='bbox_pred' + name, param_attr=ParamAttr( name='bbox_pred%s_w' % name, initializer=Normal( loc=0.0, scale=0.001), learning_rate=wb_scalar), bias_attr=ParamAttr( name='bbox_pred%s_b' % name, learning_rate=wb_scalar * 2, regularizer=L2Decay(0.))) return cls_score, bbox_pred def get_loss(self, rcnn_pred_list, rcnn_target_list, rcnn_loss_weight_list): """ Get bbox_head loss. Args: rcnn_pred_list(List): Cascade RCNN's head's output including bbox_pred and cls_score rcnn_target_list(List): Cascade rcnn's bbox and label target rcnn_loss_weight_list(List): The weight of location and class loss Return: loss_cls(Variable): bbox_head loss. loss_bbox(Variable): bbox_head loss. """ loss_dict = {} for i, (rcnn_pred, rcnn_target ) in enumerate(zip(rcnn_pred_list, rcnn_target_list)): labels_int64 = fluid.layers.cast(x=rcnn_target[1], dtype='int64') labels_int64.stop_gradient = True loss_cls = fluid.layers.softmax_with_cross_entropy( logits=rcnn_pred[0], label=labels_int64, numeric_stable_mode=True, ) loss_cls = fluid.layers.reduce_mean( loss_cls, name='loss_cls_' + str(i)) * rcnn_loss_weight_list[i] loss_bbox = fluid.layers.smooth_l1( x=rcnn_pred[1], y=rcnn_target[2], inside_weight=rcnn_target[3], outside_weight=rcnn_target[4], sigma=1.0, # detectron use delta = 1./sigma**2 ) loss_bbox = fluid.layers.reduce_mean( loss_bbox, name='loss_bbox_' + str(i)) * rcnn_loss_weight_list[i] loss_dict['loss_cls_%d' % i] = loss_cls loss_dict['loss_loc_%d' % i] = loss_bbox return loss_dict def get_prediction(self, im_info, im_shape, roi_feat_list, rcnn_pred_list, proposal_list, cascade_bbox_reg_weights, cls_agnostic_bbox_reg=2, return_box_score=False): """ Get prediction bounding box in test stage. : Args: im_info (Variable): A 2-D LoDTensor with shape [B, 3]. B is the number of input images, each element consists of im_height, im_width, im_scale. im_shape (Variable): Actual shape of original image with shape [B, 3]. B is the number of images, each element consists of original_height, original_width, 1 rois_feat_list (List): RoI feature from RoIExtractor. rcnn_pred_list (Variable): Cascade rcnn's head's output including bbox_pred and cls_score proposal_list (List): RPN proposal boxes. cascade_bbox_reg_weights (List): BBox decode var. cls_agnostic_bbox_reg(Int): BBox regressor are class agnostic Returns: pred_result(Variable): Prediction result with shape [N, 6]. Each row has 6 values: [label, confidence, xmin, ymin, xmax, ymax]. N is the total number of prediction. """ self.im_scale = fluid.layers.slice(im_info, [1], starts=[2], ends=[3]) boxes_cls_prob_l = [] rcnn_pred = rcnn_pred_list[-1] # stage 3 repreat_num = 1 repreat_num = 3 bbox_reg_w = cascade_bbox_reg_weights[-1] for i in range(repreat_num): # cls score if i < 2: cls_score, _ = self.get_output( roi_feat_list[-1], # roi_feat_3 name='_' + str(i + 1) if i > 0 else '') else: cls_score = rcnn_pred[0] cls_prob = fluid.layers.softmax(cls_score, use_cudnn=False) boxes_cls_prob_l.append(cls_prob) boxes_cls_prob_mean = ( boxes_cls_prob_l[0] + boxes_cls_prob_l[1] + boxes_cls_prob_l[2] ) / 3.0 # bbox pred proposals_boxes = proposal_list[-1] im_scale_lod = fluid.layers.sequence_expand(self.im_scale, proposals_boxes) proposals_boxes = proposals_boxes / im_scale_lod bbox_pred = rcnn_pred[1] bbox_pred_new = fluid.layers.reshape(bbox_pred, (-1, cls_agnostic_bbox_reg, 4)) if cls_agnostic_bbox_reg == 2: # only use fg box delta to decode box bbox_pred_new = fluid.layers.slice( bbox_pred_new, axes=[1], starts=[1], ends=[2]) bbox_pred_new = fluid.layers.expand(bbox_pred_new, [1, self.num_classes, 1]) decoded_box = fluid.layers.box_coder( prior_box=proposals_boxes, prior_box_var=bbox_reg_w, target_box=bbox_pred_new, code_type='decode_center_size', box_normalized=False, axis=1) box_out = fluid.layers.box_clip(input=decoded_box, im_info=im_shape) if return_box_score: return {'bbox': box_out, 'score': boxes_cls_prob_mean} pred_result = self.nms(bboxes=box_out, scores=boxes_cls_prob_mean) return {"bbox": pred_result} @register class CascadeXConvNormHead(object): """ RCNN head with serveral convolution layers Args: conv_num (int): num of convolution layers for the rcnn head conv_dim (int): num of filters for the conv layers mlp_dim (int): num of filters for the fc layers """ __shared__ = ['norm_type', 'freeze_norm'] def __init__(self, num_conv=4, conv_dim=256, mlp_dim=1024, norm_type=None, freeze_norm=False): super(CascadeXConvNormHead, self).__init__() self.conv_dim = conv_dim self.mlp_dim = mlp_dim self.num_conv = num_conv self.norm_type = norm_type self.freeze_norm = freeze_norm def __call__(self, roi_feat, wb_scalar=1.0, name=''): conv = roi_feat fan = self.conv_dim * 3 * 3 initializer = MSRA(uniform=False, fan_in=fan) for i in range(self.num_conv): name = 'bbox_head_conv' + str(i) conv = ConvNorm( conv, self.conv_dim, 3, act='relu', initializer=initializer, norm_type=self.norm_type, freeze_norm=self.freeze_norm, lr_scale=wb_scalar, name=name, norm_name=name) fan = conv.shape[1] * conv.shape[2] * conv.shape[3] head_heat = fluid.layers.fc(input=conv, size=self.mlp_dim, act='relu', name='fc6' + name, param_attr=ParamAttr( name='fc6%s_w' % name, initializer=Xavier(fan_out=fan), learning_rate=wb_scalar), bias_attr=ParamAttr( name='fc6%s_b' % name, regularizer=L2Decay(0.), learning_rate=wb_scalar * 2)) return head_heat @register class CascadeTwoFCHead(object): """ RCNN head with serveral convolution layers Args: mlp_dim (int): num of filters for the fc layers """ def __init__(self, mlp_dim): super(CascadeTwoFCHead, self).__init__() self.mlp_dim = mlp_dim def __call__(self, roi_feat, wb_scalar=1.0, name=''): fan = roi_feat.shape[1] * roi_feat.shape[2] * roi_feat.shape[3] fc6 = fluid.layers.fc(input=roi_feat, size=self.mlp_dim, act='relu', name='fc6' + name, param_attr=ParamAttr( name='fc6%s_w' % name, initializer=Xavier(fan_out=fan), learning_rate=wb_scalar), bias_attr=ParamAttr( name='fc6%s_b' % name, learning_rate=wb_scalar * 2, regularizer=L2Decay(0.))) head_feat = fluid.layers.fc(input=fc6, size=self.mlp_dim, act='relu', name='fc7' + name, param_attr=ParamAttr( name='fc7%s_w' % name, initializer=Xavier(), learning_rate=wb_scalar), bias_attr=ParamAttr( name='fc7%s_b' % name, learning_rate=wb_scalar * 2, regularizer=L2Decay(0.))) return head_feat