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SymTime/exp/exp_long_term_forecasting.py

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from data_provider.data_factory import data_provider
from exp.exp_basic import Exp_Basic
from utils.tools import EarlyStopping, adjust_learning_rate, visual
from utils.metrics import metric
import torch
import torch.nn as nn
from torch import optim
import os
import time
import warnings
import numpy as np
from utils.dtw_metric import dtw, accelerated_dtw
warnings.filterwarnings("ignore")
class Exp_Long_Term_Forecast(Exp_Basic):
def __init__(self, args):
super(Exp_Long_Term_Forecast, self).__init__(args)
def _get_data(self, flag):
data_set, data_loader = data_provider(self.args, flag)
return data_set, data_loader
def _select_optimizer(self):
model_optim = optim.Adam(self.model.parameters(), lr=self.args.learning_rate)
return model_optim
def _select_criterion(self):
criterion = nn.MSELoss()
return criterion
def vali(self, vali_data, vali_loader, criterion):
total_loss = []
self.model.eval()
with torch.no_grad():
for i, (batch_x, batch_y, batch_x_mark, batch_y_mark) in enumerate(
vali_loader
):
batch_x = batch_x.float().to(self.device)
batch_y = batch_y.float()
# encoder - decoder
if self.args.use_amp:
with torch.cuda.amp.autocast():
outputs = self.model(batch_x)
else:
outputs = self.model(batch_x)
f_dim = -1 if self.args.features == "MS" else 0
outputs = outputs[:, -self.args.pred_len :, f_dim:]
batch_y = batch_y[:, -self.args.pred_len :, f_dim:].to(self.device)
pred = outputs.detach().cpu()
true = batch_y.detach().cpu()
loss = criterion(pred, true)
total_loss.append(loss)
total_loss = np.average(total_loss)
self.model.train()
return total_loss
def train(self, setting):
"""进行模型训练"""
# 获得训练使用的训练集,验证集,测试集
train_data, train_loader = self._get_data(flag="train")
vali_data, vali_loader = self._get_data(flag="val")
test_data, test_loader = self._get_data(flag="test")
path = os.path.join(self.args.checkpoints, setting)
if not os.path.exists(path):
os.makedirs(path)
# 获取当前的时间
time_now = time.time()
train_steps = len(train_loader)
early_stopping = EarlyStopping(patience=self.args.patience, verbose=True)
model_optim = self._select_optimizer()
criterion = self._select_criterion()
if self.args.use_amp:
scaler = torch.cuda.amp.GradScaler()
for epoch in range(self.args.train_epochs):
iter_count = 0
train_loss = []
self.model.train()
# 每个Epoch所用的时间
epoch_time = time.time()
for i, (batch_x, batch_y, batch_x_mark, batch_y_mark) in enumerate(
train_loader
):
iter_count += 1
model_optim.zero_grad()
batch_x = batch_x.float().to(self.device)
batch_y = batch_y.float().to(self.device)
# encoder - decoder
if self.args.use_amp:
with torch.cuda.amp.autocast():
outputs = self.model(batch_x)
f_dim = -1 if self.args.features == "MS" else 0
outputs = outputs[:, -self.args.pred_len :, f_dim:]
batch_y = batch_y[:, -self.args.pred_len :, f_dim:].to(
self.device
)
loss = criterion(outputs, batch_y)
train_loss.append(loss.item())
else:
outputs = self.model(batch_x)
f_dim = -1 if self.args.features == "MS" else 0
outputs = outputs[:, -self.args.pred_len :, f_dim:]
batch_y = batch_y[:, -self.args.pred_len :, f_dim:].to(self.device)
loss = criterion(outputs, batch_y)
train_loss.append(loss.item())
if (i + 1) % 100 == 0:
print(
"\titers: {0}, epoch: {1} | loss: {2:.7f}".format(
i + 1, epoch + 1, loss.item()
)
)
speed = (time.time() - time_now) / iter_count
left_time = speed * (
(self.args.train_epochs - epoch) * train_steps - i
)
print(
"\tspeed: {:.4f}s/iter; left time: {:.4f}s".format(
speed, left_time
)
)
iter_count = 0
time_now = time.time()
if self.args.use_amp:
scaler.scale(loss).backward()
scaler.step(model_optim)
scaler.update()
else:
loss.backward()
model_optim.step()
print("Epoch: {} cost time: {}".format(epoch + 1, time.time() - epoch_time))
train_loss = np.average(train_loss)
vali_loss = self.vali(vali_data, vali_loader, criterion)
test_loss = self.vali(test_data, test_loader, criterion)
print(
"Epoch: {0}, Steps: {1} | Train Loss: {2:.7f} Vali Loss: {3:.7f} Test Loss: {4:.7f}".format(
epoch + 1, train_steps, train_loss, vali_loss, test_loss
)
)
early_stopping(vali_loss, self.model, path)
if early_stopping.early_stop:
print("Early stopping")
break
adjust_learning_rate(model_optim, epoch + 1, self.args)
best_model_path = path + "/" + "checkpoint.pth"
self.model.load_state_dict(torch.load(best_model_path))
return self.model
def test(self, setting, test=0):
test_data, test_loader = self._get_data(flag="test")
if test:
print("loading model")
self.model.load_state_dict(
torch.load(os.path.join("./checkpoints/" + setting, "checkpoint.pth"))
)
preds = []
trues = []
folder_path = "./test_results/" + setting + "/"
if not os.path.exists(folder_path):
os.makedirs(folder_path)
self.model.eval()
with torch.no_grad():
for i, (batch_x, batch_y, batch_x_mark, batch_y_mark) in enumerate(
test_loader
):
batch_x = batch_x.float().to(self.device)
batch_y = batch_y.float().to(self.device)
# encoder - decoder
if self.args.use_amp:
with torch.cuda.amp.autocast():
outputs = self.model(batch_x)
else:
outputs = self.model(batch_x)
f_dim = -1 if self.args.features == "MS" else 0
outputs = outputs[:, -self.args.pred_len :, :]
batch_y = batch_y[:, -self.args.pred_len :, :].to(self.device)
outputs = outputs.detach().cpu().numpy()
batch_y = batch_y.detach().cpu().numpy()
if test_data.scale and self.args.inverse:
shape = outputs.shape
outputs = test_data.inverse_transform(
outputs.reshape(shape[0] * shape[1], -1)
).reshape(shape)
batch_y = test_data.inverse_transform(
batch_y.reshape(shape[0] * shape[1], -1)
).reshape(shape)
outputs = outputs[:, :, f_dim:]
batch_y = batch_y[:, :, f_dim:]
pred = outputs
true = batch_y
preds.append(pred)
trues.append(true)
if i % 20 == 0:
input = batch_x.detach().cpu().numpy()
if test_data.scale and self.args.inverse:
shape = input.shape
input = test_data.inverse_transform(
input.reshape(shape[0] * shape[1], -1)
).reshape(shape)
gt = np.concatenate((input[0, :, -1], true[0, :, -1]), axis=0)
pd = np.concatenate((input[0, :, -1], pred[0, :, -1]), axis=0)
visual(gt, pd, os.path.join(folder_path, str(i) + ".pdf"))
preds = np.concatenate(preds, axis=0)
trues = np.concatenate(trues, axis=0)
print("test shape:", preds.shape, trues.shape)
preds = preds.reshape(-1, preds.shape[-2], preds.shape[-1])
trues = trues.reshape(-1, trues.shape[-2], trues.shape[-1])
print("test shape:", preds.shape, trues.shape)
# result save
folder_path = "./results/" + setting + "/"
if not os.path.exists(folder_path):
os.makedirs(folder_path)
# dtw calculation
if self.args.use_dtw:
dtw_list = []
manhattan_distance = lambda x, y: np.abs(x - y)
for i in range(preds.shape[0]):
x = preds[i].reshape(-1, 1)
y = trues[i].reshape(-1, 1)
if i % 100 == 0:
print("calculating dtw iter:", i)
d, _, _, _ = accelerated_dtw(x, y, dist=manhattan_distance)
dtw_list.append(d)
dtw = np.array(dtw_list).mean()
else:
dtw = "not calculated"
mae, mse, rmse, mape, mspe = metric(preds, trues)
print("mse:{}, mae:{}, dtw:{}".format(mse, mae, dtw))
f = open("result_long_term_forecast.txt", "a")
f.write(setting + " \n")
f.write("mse:{}, mae:{}, dtw:{}".format(mse, mae, dtw))
f.write("\n")
f.write("\n")
f.close()
np.save(folder_path + "metrics.npy", np.array([mae, mse, rmse, mape, mspe]))
np.save(folder_path + "pred.npy", preds)
np.save(folder_path + "true.npy", trues)
return
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