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train_multi_step.py
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train_multi_step.py
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import torch
import numpy as np
import argparse
import time
from util import *
from trainer import Trainer
from net import gtnet
def str_to_bool(value):
if isinstance(value, bool):
return value
if value.lower() in {'false', 'f', '0', 'no', 'n'}:
return False
elif value.lower() in {'true', 't', '1', 'yes', 'y'}:
return True
raise ValueError(f'{value} is not a valid boolean value')
parser = argparse.ArgumentParser()
parser.add_argument('--device',type=str,default='cuda:1',help='')
parser.add_argument('--data',type=str,default='data/METR-LA',help='data path')
parser.add_argument('--adj_data', type=str,default='data/sensor_graph/adj_mx.pkl',help='adj data path')
parser.add_argument('--gcn_true', type=str_to_bool, default=True, help='whether to add graph convolution layer')
parser.add_argument('--buildA_true', type=str_to_bool, default=True,help='whether to construct adaptive adjacency matrix')
parser.add_argument('--load_static_feature', type=str_to_bool, default=False,help='whether to load static feature')
parser.add_argument('--cl', type=str_to_bool, default=True,help='whether to do curriculum learning')
parser.add_argument('--gcn_depth',type=int,default=2,help='graph convolution depth')
parser.add_argument('--num_nodes',type=int,default=207,help='number of nodes/variables')
parser.add_argument('--dropout',type=float,default=0.3,help='dropout rate')
parser.add_argument('--subgraph_size',type=int,default=20,help='k')
parser.add_argument('--node_dim',type=int,default=40,help='dim of nodes')
parser.add_argument('--dilation_exponential',type=int,default=1,help='dilation exponential')
parser.add_argument('--conv_channels',type=int,default=32,help='convolution channels')
parser.add_argument('--residual_channels',type=int,default=32,help='residual channels')
parser.add_argument('--skip_channels',type=int,default=64,help='skip channels')
parser.add_argument('--end_channels',type=int,default=128,help='end channels')
parser.add_argument('--in_dim',type=int,default=2,help='inputs dimension')
parser.add_argument('--seq_in_len',type=int,default=12,help='input sequence length')
parser.add_argument('--seq_out_len',type=int,default=12,help='output sequence length')
parser.add_argument('--layers',type=int,default=3,help='number of layers')
parser.add_argument('--batch_size',type=int,default=64,help='batch size')
parser.add_argument('--learning_rate',type=float,default=0.001,help='learning rate')
parser.add_argument('--weight_decay',type=float,default=0.0001,help='weight decay rate')
parser.add_argument('--clip',type=int,default=5,help='clip')
parser.add_argument('--step_size1',type=int,default=2500,help='step_size')
parser.add_argument('--step_size2',type=int,default=100,help='step_size')
parser.add_argument('--epochs',type=int,default=100,help='')
parser.add_argument('--print_every',type=int,default=50,help='')
parser.add_argument('--seed',type=int,default=101,help='random seed')
parser.add_argument('--save',type=str,default='./save/',help='save path')
parser.add_argument('--expid',type=int,default=1,help='experiment id')
parser.add_argument('--propalpha',type=float,default=0.05,help='prop alpha')
parser.add_argument('--tanhalpha',type=float,default=3,help='adj alpha')
parser.add_argument('--num_split',type=int,default=1,help='number of splits for graphs')
parser.add_argument('--runs',type=int,default=10,help='number of runs')
args = parser.parse_args()
torch.set_num_threads(3)
def main(runid):
# torch.manual_seed(args.seed)
# torch.backends.cudnn.deterministic = True
# torch.backends.cudnn.benchmark = False
# np.random.seed(args.seed)
#load data
device = torch.device(args.device)
dataloader = load_dataset(args.data, args.batch_size, args.batch_size, args.batch_size)
scaler = dataloader['scaler']
predefined_A = load_adj(args.adj_data)
predefined_A = torch.tensor(predefined_A)-torch.eye(args.num_nodes)
predefined_A = predefined_A.to(device)
# if args.load_static_feature:
# static_feat = load_node_feature('data/sensor_graph/location.csv')
# else:
# static_feat = None
model = gtnet(args.gcn_true, args.buildA_true, args.gcn_depth, args.num_nodes,
device, predefined_A=predefined_A,
dropout=args.dropout, subgraph_size=args.subgraph_size,
node_dim=args.node_dim,
dilation_exponential=args.dilation_exponential,
conv_channels=args.conv_channels, residual_channels=args.residual_channels,
skip_channels=args.skip_channels, end_channels= args.end_channels,
seq_length=args.seq_in_len, in_dim=args.in_dim, out_dim=args.seq_out_len,
layers=args.layers, propalpha=args.propalpha, tanhalpha=args.tanhalpha, layer_norm_affline=True)
print(args)
print('The recpetive field size is', model.receptive_field)
nParams = sum([p.nelement() for p in model.parameters()])
print('Number of model parameters is', nParams)
engine = Trainer(model, args.learning_rate, args.weight_decay, args.clip, args.step_size1, args.seq_out_len, scaler, device, args.cl)
print("start training...",flush=True)
his_loss =[]
val_time = []
train_time = []
minl = 1e5
for i in range(1,args.epochs+1):
train_loss = []
train_mape = []
train_rmse = []
t1 = time.time()
dataloader['train_loader'].shuffle()
for iter, (x, y) in enumerate(dataloader['train_loader'].get_iterator()):
trainx = torch.Tensor(x).to(device)
trainx= trainx.transpose(1, 3)
trainy = torch.Tensor(y).to(device)
trainy = trainy.transpose(1, 3)
if iter%args.step_size2==0:
perm = np.random.permutation(range(args.num_nodes))
num_sub = int(args.num_nodes/args.num_split)
for j in range(args.num_split):
if j != args.num_split-1:
id = perm[j * num_sub:(j + 1) * num_sub]
else:
id = perm[j * num_sub:]
id = torch.tensor(id).to(device)
tx = trainx[:, :, id, :]
ty = trainy[:, :, id, :]
metrics = engine.train(tx, ty[:,0,:,:],id)
train_loss.append(metrics[0])
train_mape.append(metrics[1])
train_rmse.append(metrics[2])
if iter % args.print_every == 0 :
log = 'Iter: {:03d}, Train Loss: {:.4f}, Train MAPE: {:.4f}, Train RMSE: {:.4f}'
print(log.format(iter, train_loss[-1], train_mape[-1], train_rmse[-1]),flush=True)
t2 = time.time()
train_time.append(t2-t1)
#validation
valid_loss = []
valid_mape = []
valid_rmse = []
s1 = time.time()
for iter, (x, y) in enumerate(dataloader['val_loader'].get_iterator()):
testx = torch.Tensor(x).to(device)
testx = testx.transpose(1, 3)
testy = torch.Tensor(y).to(device)
testy = testy.transpose(1, 3)
metrics = engine.eval(testx, testy[:,0,:,:])
valid_loss.append(metrics[0])
valid_mape.append(metrics[1])
valid_rmse.append(metrics[2])
s2 = time.time()
log = 'Epoch: {:03d}, Inference Time: {:.4f} secs'
print(log.format(i,(s2-s1)))
val_time.append(s2-s1)
mtrain_loss = np.mean(train_loss)
mtrain_mape = np.mean(train_mape)
mtrain_rmse = np.mean(train_rmse)
mvalid_loss = np.mean(valid_loss)
mvalid_mape = np.mean(valid_mape)
mvalid_rmse = np.mean(valid_rmse)
his_loss.append(mvalid_loss)
log = 'Epoch: {:03d}, Train Loss: {:.4f}, Train MAPE: {:.4f}, Train RMSE: {:.4f}, Valid Loss: {:.4f}, Valid MAPE: {:.4f}, Valid RMSE: {:.4f}, Training Time: {:.4f}/epoch'
print(log.format(i, mtrain_loss, mtrain_mape, mtrain_rmse, mvalid_loss, mvalid_mape, mvalid_rmse, (t2 - t1)),flush=True)
if mvalid_loss<minl:
torch.save(engine.model.state_dict(), args.save + "exp" + str(args.expid) + "_" + str(runid) +".pth")
minl = mvalid_loss
print("Average Training Time: {:.4f} secs/epoch".format(np.mean(train_time)))
print("Average Inference Time: {:.4f} secs".format(np.mean(val_time)))
bestid = np.argmin(his_loss)
engine.model.load_state_dict(torch.load(args.save + "exp" + str(args.expid) + "_" + str(runid) +".pth"))
print("Training finished")
print("The valid loss on best model is", str(round(his_loss[bestid],4)))
#valid data
outputs = []
realy = torch.Tensor(dataloader['y_val']).to(device)
realy = realy.transpose(1,3)[:,0,:,:]
for iter, (x, y) in enumerate(dataloader['val_loader'].get_iterator()):
testx = torch.Tensor(x).to(device)
testx = testx.transpose(1,3)
with torch.no_grad():
preds = engine.model(testx)
preds = preds.transpose(1,3)
outputs.append(preds.squeeze())
yhat = torch.cat(outputs,dim=0)
yhat = yhat[:realy.size(0),...]
pred = scaler.inverse_transform(yhat)
vmae, vmape, vrmse = metric(pred,realy)
#test data
outputs = []
realy = torch.Tensor(dataloader['y_test']).to(device)
realy = realy.transpose(1, 3)[:, 0, :, :]
for iter, (x, y) in enumerate(dataloader['test_loader'].get_iterator()):
testx = torch.Tensor(x).to(device)
testx = testx.transpose(1, 3)
with torch.no_grad():
preds = engine.model(testx)
preds = preds.transpose(1, 3)
outputs.append(preds.squeeze())
yhat = torch.cat(outputs, dim=0)
yhat = yhat[:realy.size(0), ...]
mae = []
mape = []
rmse = []
for i in range(args.seq_out_len):
pred = scaler.inverse_transform(yhat[:, :, i])
real = realy[:, :, i]
metrics = metric(pred, real)
log = 'Evaluate best model on test data for horizon {:d}, Test MAE: {:.4f}, Test MAPE: {:.4f}, Test RMSE: {:.4f}'
print(log.format(i + 1, metrics[0], metrics[1], metrics[2]))
mae.append(metrics[0])
mape.append(metrics[1])
rmse.append(metrics[2])
return vmae, vmape, vrmse, mae, mape, rmse
if __name__ == "__main__":
vmae = []
vmape = []
vrmse = []
mae = []
mape = []
rmse = []
for i in range(args.runs):
vm1, vm2, vm3, m1, m2, m3 = main(i)
vmae.append(vm1)
vmape.append(vm2)
vrmse.append(vm3)
mae.append(m1)
mape.append(m2)
rmse.append(m3)
mae = np.array(mae)
mape = np.array(mape)
rmse = np.array(rmse)
amae = np.mean(mae,0)
amape = np.mean(mape,0)
armse = np.mean(rmse,0)
smae = np.std(mae,0)
smape = np.std(mape,0)
srmse = np.std(rmse,0)
print('\n\nResults for 10 runs\n\n')
#valid data
print('valid\tMAE\tRMSE\tMAPE')
log = 'mean:\t{:.4f}\t{:.4f}\t{:.4f}'
print(log.format(np.mean(vmae),np.mean(vrmse),np.mean(vmape)))
log = 'std:\t{:.4f}\t{:.4f}\t{:.4f}'
print(log.format(np.std(vmae),np.std(vrmse),np.std(vmape)))
print('\n\n')
#test data
print('test|horizon\tMAE-mean\tRMSE-mean\tMAPE-mean\tMAE-std\tRMSE-std\tMAPE-std')
for i in [2,5,11]:
log = '{:d}\t{:.4f}\t{:.4f}\t{:.4f}\t{:.4f}\t{:.4f}\t{:.4f}'
print(log.format(i+1, amae[i], armse[i], amape[i], smae[i], srmse[i], smape[i]))