""" Author: Mélanie Gaillochet Date: 2020-11-20 """ from comet_ml import Experiment import os import copy from collections import defaultdict from tqdm import tqdm import matplotlib.pyplot as plt import torch from Base.base_solver import BaseSolver from Utils.utils import add_dic_values, default0, to_onehot class Solver(BaseSolver): """ This solver performs one forward pass through the model with the labeled data """ def __init__(self, config, test_dataloader, **kwargs): super().__init__(config, test_dataloader, **kwargs) print('Initializing Vanilla solver') self.loss_name_list = ['total', 'model'] def train_step(self, data, target): """ We implement the logic of one train step - return any metrics you need to summarize """ # We set the model to training mode self.models_dic['model'].train() # We zero the parameter gradients self.optimizers_dic['model'].zero_grad() data, target = data.to(self.device, dtype=torch.float), target.to(self.device) #### Supervised part #### # We compute the model loss (supervised loss) using S(x) supervised_output, _ = self.models_dic['model'](data) onehot_target = to_onehot(target.squeeze(1), self.models_dic['model'].out_channels) model_loss = self.model_loss(supervised_output, onehot_target) train_loss = 1.0 * model_loss if self.activate_plot and (self.epoch % self.log_every == 0) and (self.train_batch_idx in [0, 1, 2]): self.plot_training_data_pred(data, target, supervised_output, indices=self.idx_l, type='Train') self.plot_training_data_pred_contour(data, target, supervised_output, indices=self.idx_l, type='Train') # We do backward propagation train_loss.backward() self.optimizers_dic['model'].step() loss_dic = { 'total': train_loss.item(), 'model': model_loss.item() } # We compute the metrics train_acc_dic = self.compute_metrics(supervised_output, onehot_target) return supervised_output, loss_dic, train_acc_dic def validation(self, val_dataloader, mode='val'): assert mode == 'val' or mode == 'test' # We set model in evaluation mode self.models_dic['model'].eval() val_dataloader.dataset.training = False # We initialize loss and accuracy val_acc_dic = defaultdict(default0) val_loss_dic = {} for key in self.loss_name_list: val_loss_dic[key] = 0 # We iterate through validation batches with torch.no_grad(): for batch_idx, (val_data, val_target, idx_list) in enumerate(val_dataloader): # print('val_batch {}, val_idx {}'.format(batch_idx, idx_list)) val_data = val_data.to(self.device, dtype=torch.float) val_target = val_target.to(self.device) val_output, _ = self.models_dic['model'](val_data) #### Supervised loss #### # Computing the model loss (supervised loss) using S(x) onehot_target = to_onehot(val_target.squeeze(1), self.models_dic['model'].out_channels) model_loss = self.model_loss(val_output, onehot_target) total_loss = 1.0 * model_loss batch_val_loss_dic = { 'total': total_loss.item(), 'model': model_loss.item() } # We compute the metrics batch_val_acc_dic = self.compute_metrics(val_output, onehot_target) # We add the loss and metrics for each batch # Note for accuracy, we put the batch values first because initial val_acc_dic is empty val_loss_dic = add_dic_values(val_loss_dic, batch_val_loss_dic) val_acc_dic = add_dic_values(batch_val_acc_dic, val_acc_dic) if self.activate_plot and (mode == 'val') and (self.epoch % self.log_every == 0) and batch_idx in [0, 1, 2, 3]: self.plot_val_data_pred(val_data, val_target, val_output, batch_idx, img_idx=0) self.plot_val_data_pred_contour(val_data, val_target, val_output, batch_idx, img_idx=0) # We compute average accuracy and loss over all batches avg_val_loss_dic = self.compute_mean_value(val_loss_dic, len(val_dataloader)) avg_val_acc_dic = self.compute_mean_value(val_acc_dic, len(val_dataloader)) return avg_val_loss_dic, avg_val_acc_dic, True