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import torch |
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from torch import nn |
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import torch.nn.functional as F |
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from configs.paths_config import model_paths |
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from models.dex_vgg import VGG |
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class AgingLoss(nn.Module): |
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def __init__(self, opts): |
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super(AgingLoss, self).__init__() |
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self.age_net = VGG() |
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ckpt = torch.load(model_paths['age_predictor'], map_location="cpu")['state_dict'] |
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ckpt = {k.replace('-', '_'): v for k, v in ckpt.items()} |
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self.age_net.load_state_dict(ckpt) |
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self.age_net.cuda() |
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self.age_net.eval() |
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self.min_age = 0 |
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self.max_age = 100 |
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self.opts = opts |
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def __get_predicted_age(self, age_pb): |
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predict_age_pb = F.softmax(age_pb) |
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predict_age = torch.zeros(age_pb.size(0)).type_as(predict_age_pb) |
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for i in range(age_pb.size(0)): |
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for j in range(age_pb.size(1)): |
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predict_age[i] += j * predict_age_pb[i][j] |
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return predict_age |
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def extract_ages(self, x): |
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x = F.interpolate(x, size=(224, 224), mode='bilinear') |
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predict_age_pb = self.age_net(x)['fc8'] |
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predicted_age = self.__get_predicted_age(predict_age_pb) |
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return predicted_age |
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def forward(self, y_hat, y, target_ages, id_logs, label=None): |
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n_samples = y.shape[0] |
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if id_logs is None: |
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id_logs = [] |
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input_ages = self.extract_ages(y) / 100. |
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output_ages = self.extract_ages(y_hat) / 100. |
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for i in range(n_samples): |
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if len(id_logs) > i: |
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id_logs[i].update({f'input_age_{label}': float(input_ages[i]) * 100, |
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f'output_age_{label}': float(output_ages[i]) * 100, |
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f'target_age_{label}': float(target_ages[i]) * 100}) |
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else: |
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id_logs.append({f'input_age_{label}': float(input_ages[i]) * 100, |
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f'output_age_{label}': float(output_ages[i]) * 100, |
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f'target_age_{label}': float(target_ages[i]) * 100}) |
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loss = F.mse_loss(output_ages, target_ages) |
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return loss, id_logs |
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