TEXTOIR-main/open_intent_detection/methods/DOC/manager.py

from importlib import import_module
import torch
import numpy as np
import os
import copy
import logging
from torch import nn
from datetime import datetime
from sklearn.metrics import confusion_matrix, accuracy_score
from tqdm import trange, tqdm
from scipy.stats import norm as dist_model
from losses import loss_map
from utils.functions import restore_model, save_model
from utils.metrics import F_measure

class DOCManager:
    
    def __init__(self, args, data, model, logger_name = 'Detection'):

        self.logger = logging.getLogger(logger_name)
        
        self.set_model_optimizer(args, data, model)

        self.data = data 
        self.train_dataloader = data.dataloader.train_labeled_loader
        self.eval_dataloader = data.dataloader.eval_loader 
        self.test_dataloader = data.dataloader.test_loader

        self.loss_fct = loss_map[args.loss_fct]
        
        if args.train:
            self.best_mu_stds = None

        else:
            restore_model(self.model, args.model_output_dir)
        
    def set_model_optimizer(self, args, data, model):
    
        self.model = model.set_model(args, 'bert')  
        self.optimizer, self.scheduler = model.set_optimizer(self.model, data.dataloader.num_train_examples, args.train_batch_size, \
                args.num_train_epochs, args.lr, args.warmup_proportion)
        self.device = model.device
    
    
    def train(self, args, data):     
        best_model = None
        wait = 0
        best_eval_score = 0

        for epoch in trange(int(args.num_train_epochs), desc="Epoch"):
            self.model.train()
            tr_loss = 0
            nb_tr_examples, nb_tr_steps = 0, 0
            
            for step, batch in enumerate(tqdm(self.train_dataloader, desc="Iteration")):
                batch = tuple(t.to(self.device) for t in batch)
                input_ids, input_mask, segment_ids, label_ids = batch
                with torch.set_grad_enabled(True):
            
                    loss = self.model(input_ids, segment_ids, input_mask, label_ids, mode='train', loss_fct=self.loss_fct)

                    self.optimizer.zero_grad()
                    loss.backward()
                    self.optimizer.step()
                    self.scheduler.step()
                    
                    tr_loss += loss.item()
                    
                    nb_tr_examples += input_ids.size(0)
                    nb_tr_steps += 1

            loss = tr_loss / nb_tr_steps

            y_true, y_pred = self.get_outputs(args, data, mode = 'eval')

            eval_score = round(accuracy_score(y_true, y_pred) * 100, 2)
            
            eval_results = {
                'train_loss': loss,
                'eval_score': eval_score,
                'best_eval_score':best_eval_score,
            }
            self.logger.info("***** Epoch: %s: Eval results *****", str(epoch + 1))
            for key in sorted(eval_results.keys()):
                self.logger.info("  %s = %s", key, str(eval_results[key]))  

            if eval_score > best_eval_score:
                best_model = copy.deepcopy(self.model)
                wait = 0
                best_eval_score = eval_score 
                
            elif eval_score > 0:                
                wait += 1
                if wait >= args.wait_patient:
                    break

        self.model = best_model 

        if args.save_model:
            save_model(self.model, args.model_output_dir)
            np.save(os.path.join(args.method_output_dir, 'mu_stds.npy'), self.best_mu_stds)

    def test(self, args, data, show=False):
        
        mu_stds = self.get_outputs(args, data, mode = 'train', get_mu_stds = True)
        y_true, y_pred = self.get_outputs(args, data, mode = 'test', mu_stds = mu_stds)

        cm = confusion_matrix(y_true, y_pred)
        test_results = F_measure(cm)

        acc = round(accuracy_score(y_true, y_pred) * 100, 2)
        test_results['Acc'] = acc
        
        self.logger.info
        self.logger.info("***** Test: Confusion Matrix *****")
        self.logger.info("%s", str(cm))
        self.logger.info("***** Test results *****")

        for key in sorted(test_results.keys()):
            self.logger.info("  %s = %s", key, str(test_results[key]))

        test_results['y_true'] = y_true
        test_results['y_pred'] = y_pred

        return test_results

    def get_outputs(self, args, data, mode = 'eval', get_feats = False, get_mu_stds = False, mu_stds = None):
        
        if mode == 'train':
            dataloader = self.train_dataloader
        elif mode == 'eval':
            dataloader = self.eval_dataloader
        elif mode == 'test':
            dataloader = self.test_dataloader

        self.model.eval()

        total_labels = torch.empty(0,dtype=torch.long).to(self.device)
        total_logits = torch.empty((0, data.num_labels)).to(self.device)
        total_features = torch.empty((0,args.feat_dim)).to(self.device)

        for batch in tqdm(dataloader, desc="Iteration"):

            batch = tuple(t.to(self.device) for t in batch)
            input_ids, input_mask, segment_ids, label_ids = batch
            with torch.set_grad_enabled(False):

                pooled_output, logits = self.model(input_ids, segment_ids, input_mask)

                total_labels = torch.cat((total_labels,label_ids))
                total_logits = torch.cat((total_logits, logits))
                total_features = torch.cat((total_features, pooled_output))

        if get_feats:
            
            feats = total_features.cpu().numpy()
            return feats 

        else:
            
            total_probs, y_pred = total_logits.max(dim = 1)
            y_true = total_labels.cpu().numpy()
            y_logit = total_logits.cpu().numpy()
            y_pred = y_pred.cpu().numpy()
            
            if mode == 'eval':
                return y_true, y_pred

            else:
                if get_mu_stds == True:
                    mu_stds = self.cal_mu_std(y_logit, y_true, data.num_labels)
                    return mu_stds
                else:
                    y_pred = self.classify_doc(data, args, y_logit, mu_stds)

                    return y_true, y_pred

    def classify_doc(self, data, args, y_prob, mu_stds):

        thresholds = {}
        for col in range(data.num_labels):
            threshold = max(0.5, 1 - args.scale * mu_stds[col][1])
            label = data.known_label_list[col]
            thresholds[label] = threshold
        thresholds = np.array(thresholds)
        self.logger.info('Probability thresholds of each class: %s', thresholds)
        
        y_pred = []
        for p in y_prob:
            max_class = np.argmax(p)
            max_value = np.max(p)
            threshold = max(0.5, 1 - args.scale * mu_stds[max_class][1])

            if max_value > threshold:
                y_pred.append(max_class)
            else:
                y_pred.append(data.unseen_label_id)

        return np.array(y_pred)
    
    def fit(self, prob_pos_X):
        prob_pos = [p for p in prob_pos_X] + [2 - p for p in prob_pos_X]
        pos_mu, pos_std = dist_model.fit(prob_pos)
        return pos_mu, pos_std

    def cal_mu_std(self, y_prob, trues, num_labels):

        mu_stds = []
        for i in range(num_labels):
            pos_mu, pos_std = self.fit(y_prob[trues == i, i])
            mu_stds.append([pos_mu, pos_std])

        return mu_stds