import torch import torch.nn as nn from tqdm import tqdm from utils import categorical_accuracy def loss_fn(outputs, targets): return nn.CrossEntropyLoss()(outputs, targets) def train_fn(data_loader, model, optimizer, device, scheduler): model.train() train_loss, train_acc = 0.0, 0.0 for bi, d in tqdm(enumerate(data_loader), total=len(data_loader)): ids = d["ids"] token_type_ids = d["token_type_ids"] mask = d["mask"] targets = d["targets"] ids = ids.to(device, dtype=torch.long) token_type_ids = token_type_ids.to(device, dtype=torch.long) mask = mask.to(device, dtype=torch.long) targets = targets.to(device, dtype=torch.long) optimizer.zero_grad() outputs = model( ids=ids, mask=mask, token_type_ids=token_type_ids ) loss = loss_fn(outputs, targets) loss.backward() optimizer.step() scheduler.step() train_loss += loss.item() pred_labels = torch.argmax(outputs, dim=1) # (pred_labels == targets).sum().item() train_acc += categorical_accuracy(outputs, targets).item() train_loss /= len(data_loader) train_acc /= len(data_loader) return train_loss, train_acc def eval_fn(data_loader, model, device): model.eval() eval_loss, eval_acc = 0.0, 0.0 fin_targets = [] fin_outputs = [] with torch.no_grad(): for bi, d in tqdm(enumerate(data_loader), total=len(data_loader)): ids = d["ids"] token_type_ids = d["token_type_ids"] mask = d["mask"] targets = d["targets"] ids = ids.to(device, dtype=torch.long) token_type_ids = token_type_ids.to(device, dtype=torch.long) mask = mask.to(device, dtype=torch.long) targets = targets.to(device, dtype=torch.long) outputs = model( ids=ids, mask=mask, token_type_ids=token_type_ids ) loss = loss_fn(outputs, targets) eval_loss += loss.item() pred_labels = torch.argmax(outputs, axis=1) # (pred_labels == targets).sum().item() eval_acc += categorical_accuracy(outputs, targets).item() fin_targets.extend(targets.cpu().detach().numpy().tolist()) fin_outputs.extend(torch.argmax( outputs, dim=1).cpu().detach().numpy().tolist()) eval_loss /= len(data_loader) eval_acc /= len(data_loader) return fin_outputs, fin_targets, eval_loss, eval_acc def predict_fn(data_loader, model, device, extract_features=False): model.eval() fin_outputs = [] extracted_features =[] with torch.no_grad(): for bi, d in tqdm(enumerate(data_loader), total=len(data_loader)): ids = d["ids"] token_type_ids = d["token_type_ids"] mask = d["mask"] # targets = d["targets"] ids = ids.to(device, dtype=torch.long) token_type_ids = token_type_ids.to(device, dtype=torch.long) mask = mask.to(device, dtype=torch.long) outputs = model( ids=ids, mask=mask, token_type_ids=token_type_ids ) if extract_features: extracted_features.extend( model.extract_features( ids=ids, mask=mask, token_type_ids=token_type_ids ).cpu().detach().numpy().tolist()) print("1",torch.argmax(outputs, dim=1)) print("2",torch.argmax(outputs, dim=1).cpu()) print("3",torch.argmax(outputs, dim=1).cpu().numpy()) fin_outputs.extend(torch.argmax( outputs, dim=1).cpu().detach().numpy().tolist()) return fin_outputs, extracted_features