# copyright (c) 2021 PaddlePaddle Authors. All Rights Reserve. # # 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 from paddle import nn import paddle class SDMGRLoss(nn.Layer): def __init__(self, node_weight=1.0, edge_weight=1.0, ignore=0): super().__init__() self.loss_node = nn.CrossEntropyLoss(ignore_index=ignore) self.loss_edge = nn.CrossEntropyLoss(ignore_index=-1) self.node_weight = node_weight self.edge_weight = edge_weight self.ignore = ignore def pre_process(self, gts, tag): gts, tag = gts.numpy(), tag.numpy().tolist() temp_gts = [] batch = len(tag) for i in range(batch): num, recoder_len = tag[i][0], tag[i][1] temp_gts.append( paddle.to_tensor( gts[i, :num, :num + 1], dtype='int64')) return temp_gts def accuracy(self, pred, target, topk=1, thresh=None): """Calculate accuracy according to the prediction and target. Args: pred (torch.Tensor): The model prediction, shape (N, num_class) target (torch.Tensor): The target of each prediction, shape (N, ) topk (int | tuple[int], optional): If the predictions in ``topk`` matches the target, the predictions will be regarded as correct ones. Defaults to 1. thresh (float, optional): If not None, predictions with scores under this threshold are considered incorrect. Default to None. Returns: float | tuple[float]: If the input ``topk`` is a single integer, the function will return a single float as accuracy. If ``topk`` is a tuple containing multiple integers, the function will return a tuple containing accuracies of each ``topk`` number. """ assert isinstance(topk, (int, tuple)) if isinstance(topk, int): topk = (topk, ) return_single = True else: return_single = False maxk = max(topk) if pred.shape[0] == 0: accu = [pred.new_tensor(0.) for i in range(len(topk))] return accu[0] if return_single else accu pred_value, pred_label = paddle.topk(pred, maxk, axis=1) pred_label = pred_label.transpose( [1, 0]) # transpose to shape (maxk, N) correct = paddle.equal(pred_label, (target.reshape([1, -1]).expand_as(pred_label))) res = [] for k in topk: correct_k = paddle.sum(correct[:k].reshape([-1]).astype('float32'), axis=0, keepdim=True) res.append( paddle.multiply(correct_k, paddle.to_tensor(100.0 / pred.shape[0]))) return res[0] if return_single else res def forward(self, pred, batch): node_preds, edge_preds = pred gts, tag = batch[4], batch[5] gts = self.pre_process(gts, tag) node_gts, edge_gts = [], [] for gt in gts: node_gts.append(gt[:, 0]) edge_gts.append(gt[:, 1:].reshape([-1])) node_gts = paddle.concat(node_gts) edge_gts = paddle.concat(edge_gts) node_valids = paddle.nonzero(node_gts != self.ignore).reshape([-1]) edge_valids = paddle.nonzero(edge_gts != -1).reshape([-1]) loss_node = self.loss_node(node_preds, node_gts) loss_edge = self.loss_edge(edge_preds, edge_gts) loss = self.node_weight * loss_node + self.edge_weight * loss_edge return dict( loss=loss, loss_node=loss_node, loss_edge=loss_edge, acc_node=self.accuracy( paddle.gather(node_preds, node_valids), paddle.gather(node_gts, node_valids)), acc_edge=self.accuracy( paddle.gather(edge_preds, edge_valids), paddle.gather(edge_gts, edge_valids)))