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Time-Series-Library

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Time-Series-Library / utils /tools.py

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	import os

	import numpy as np
	import torch
	import matplotlib.pyplot as plt
	import pandas as pd
	import math

	plt.switch_backend('agg')


	def adjust_learning_rate(optimizer, epoch, args):
	# lr = args.learning_rate * (0.2 ** (epoch // 2))
	if args.lradj == 'type1':
	lr_adjust = {epoch: args.learning_rate * (0.5 ** ((epoch - 1) // 1))}
	elif args.lradj == 'type2':
	lr_adjust = {
	2: 5e-5, 4: 1e-5, 6: 5e-6, 8: 1e-6,
	10: 5e-7, 15: 1e-7, 20: 5e-8
	}
	elif args.lradj == 'type3':
	lr_adjust = {epoch: args.learning_rate if epoch < 3 else args.learning_rate * (0.9 ** ((epoch - 3) // 1))}
	elif args.lradj == "cosine":
	lr_adjust = {epoch: args.learning_rate /2 * (1 + math.cos(epoch / args.train_epochs * math.pi))}
	if epoch in lr_adjust.keys():
	lr = lr_adjust[epoch]
	for param_group in optimizer.param_groups:
	param_group['lr'] = lr
	print('Updating learning rate to {}'.format(lr))


	class EarlyStopping:
	def __init__(self, patience=7, verbose=False, delta=0):
	self.patience = patience
	self.verbose = verbose
	self.counter = 0
	self.best_score = None
	self.early_stop = False
	self.val_loss_min = np.inf
	self.delta = delta

	def __call__(self, val_loss, model, path):
	score = -val_loss
	if self.best_score is None:
	self.best_score = score
	self.save_checkpoint(val_loss, model, path)
	elif score < self.best_score + self.delta:
	self.counter += 1
	print(f'EarlyStopping counter: {self.counter} out of {self.patience}')
	if self.counter >= self.patience:
	self.early_stop = True
	else:
	self.best_score = score
	self.save_checkpoint(val_loss, model, path)
	self.counter = 0

	def save_checkpoint(self, val_loss, model, path):
	if self.verbose:
	print(f'Validation loss decreased ({self.val_loss_min:.6f} --> {val_loss:.6f}). Saving model ...')
	torch.save(model.state_dict(), path + '/' + 'checkpoint.pth')
	self.val_loss_min = val_loss


	class dotdict(dict):
	"""dot.notation access to dictionary attributes"""
	__getattr__ = dict.get
	__setattr__ = dict.__setitem__
	__delattr__ = dict.__delitem__


	class StandardScaler():
	def __init__(self, mean, std):
	self.mean = mean
	self.std = std

	def transform(self, data):
	return (data - self.mean) / self.std

	def inverse_transform(self, data):
	return (data * self.std) + self.mean


	def visual(true, preds=None, name='./pic/test.pdf'):
	"""
	Results visualization
	"""
	plt.figure()
	if preds is not None:
	plt.plot(preds, label='Prediction', linewidth=2)
	plt.plot(true, label='GroundTruth', linewidth=2)
	plt.legend()
	plt.savefig(name, bbox_inches='tight')


	def adjustment(gt, pred):
	anomaly_state = False
	for i in range(len(gt)):
	if gt[i] == 1 and pred[i] == 1 and not anomaly_state:
	anomaly_state = True
	for j in range(i, 0, -1):
	if gt[j] == 0:
	break
	else:
	if pred[j] == 0:
	pred[j] = 1
	for j in range(i, len(gt)):
	if gt[j] == 0:
	break
	else:
	if pred[j] == 0:
	pred[j] = 1
	elif gt[i] == 0:
	anomaly_state = False
	if anomaly_state:
	pred[i] = 1
	return gt, pred


	def cal_accuracy(y_pred, y_true):
	return np.mean(y_pred == y_true)