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train.py
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train.py
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# By Yuxiang Sun, Dec. 4, 2019
# Email: sun.yuxiang@outlook.com
import os, argparse, time, datetime, stat, shutil
import numpy as np
import torch
import torch.nn.functional as F
from torch.autograd import Variable
from torch.utils.data import DataLoader
import torchvision.utils as vutils
from util.MF_dataset import MF_dataset
from util.augmentation import RandomFlip, RandomCrop, RandomCropOut, RandomBrightness, RandomNoise
from util.util import compute_results
from sklearn.metrics import confusion_matrix
from torch.utils.tensorboard import SummaryWriter
from model import RTFNet
#############################################################################################
parser = argparse.ArgumentParser(description='Train with pytorch')
#############################################################################################
parser.add_argument('--model_name', '-m', type=str, default='RTFNet')
#batch_size: RTFNet-152: 2; RTFNet-101: 2; RTFNet-50: 3; RTFNet-34: 10; RTFNet-18: 15;
parser.add_argument('--batch_size', '-b', type=int, default=2)
parser.add_argument('--lr_start', '-ls', type=float, default=0.01)
parser.add_argument('--gpu', '-g', type=int, default=0)
#############################################################################################
parser.add_argument('--lr_decay', '-ld', type=float, default=0.95)
parser.add_argument('--epoch_max', '-em', type=int, default=10000) # please stop training mannully
parser.add_argument('--epoch_from', '-ef', type=int, default=0)
parser.add_argument('--num_workers', '-j', type=int, default=8)
parser.add_argument('--n_class', '-nc', type=int, default=9)
parser.add_argument('--data_dir', '-dr', type=str, default='./dataset/')
args = parser.parse_args()
#############################################################################################
augmentation_methods = [
RandomFlip(prob=0.5),
RandomCrop(crop_rate=0.1, prob=1.0),
# RandomCropOut(crop_rate=0.2, prob=1.0),
# RandomBrightness(bright_range=0.15, prob=0.9),
# RandomNoise(noise_range=5, prob=0.9),
]
def train(epo, model, train_loader, optimizer):
model.train()
for it, (images, labels, names) in enumerate(train_loader):
images = Variable(images).cuda(args.gpu)
labels = Variable(labels).cuda(args.gpu)
start_t = time.time() # time.time() returns the current time
optimizer.zero_grad()
logits = model(images)
loss = F.cross_entropy(logits, labels) # Note that the cross_entropy function has already include the softmax function
loss.backward()
optimizer.step()
lr_this_epo=0
for param_group in optimizer.param_groups:
lr_this_epo = param_group['lr']
print('Train: %s, epo %s/%s, iter %s/%s, lr %.8f, %.2f img/sec, loss %.4f, time %s' \
% (args.model_name, epo, args.epoch_max, it+1, len(train_loader), lr_this_epo, len(names)/(time.time()-start_t), float(loss),
datetime.datetime.now().replace(microsecond=0)-start_datetime))
if accIter['train'] % 1 == 0:
writer.add_scalar('Train/loss', loss, accIter['train'])
view_figure = True # note that I have not colorized the GT and predictions here
if accIter['train'] % 500 == 0:
if view_figure:
input_rgb_images = vutils.make_grid(images[:,:3], nrow=8, padding=10) # can only display 3-channel images, so images[:,:3]
writer.add_image('Train/input_rgb_images', input_rgb_images, accIter['train'])
scale = max(1, 255//args.n_class) # label (0,1,2..) is invisable, multiply a constant for visualization
groundtruth_tensor = labels.unsqueeze(1) * scale # mini_batch*480*640 -> mini_batch*1*480*640
groundtruth_tensor = torch.cat((groundtruth_tensor, groundtruth_tensor, groundtruth_tensor), 1) # change to 3-channel for visualization
groudtruth_images = vutils.make_grid(groundtruth_tensor, nrow=8, padding=10)
writer.add_image('Train/groudtruth_images', groudtruth_images, accIter['train'])
predicted_tensor = logits.argmax(1).unsqueeze(1) * scale # mini_batch*args.n_class*480*640 -> mini_batch*480*640 -> mini_batch*1*480*640
predicted_tensor = torch.cat((predicted_tensor, predicted_tensor, predicted_tensor),1) # change to 3-channel for visualization, mini_batch*1*480*640
predicted_images = vutils.make_grid(predicted_tensor, nrow=8, padding=10)
writer.add_image('Train/predicted_images', predicted_images, accIter['train'])
accIter['train'] = accIter['train'] + 1
def validation(epo, model, val_loader):
model.eval()
with torch.no_grad():
for it, (images, labels, names) in enumerate(val_loader):
images = Variable(images).cuda(args.gpu)
labels = Variable(labels).cuda(args.gpu)
start_t = time.time() # time.time() returns the current time
logits = model(images)
loss = F.cross_entropy(logits, labels) # Note that the cross_entropy function has already include the softmax function
print('Val: %s, epo %s/%s, iter %s/%s, %.2f img/sec, loss %.4f, time %s' \
% (args.model_name, epo, args.epoch_max, it + 1, len(val_loader), len(names)/(time.time()-start_t), float(loss),
datetime.datetime.now().replace(microsecond=0)-start_datetime))
if accIter['val'] % 1 == 0:
writer.add_scalar('Validation/loss', loss, accIter['val'])
view_figure = False # note that I have not colorized the GT and predictions here
if accIter['val'] % 100 == 0:
if view_figure:
input_rgb_images = vutils.make_grid(images[:, :3], nrow=8, padding=10) # can only display 3-channel images, so images[:,:3]
writer.add_image('Validation/input_rgb_images', input_rgb_images, accIter['val'])
scale = max(1, 255 // args.n_class) # label (0,1,2..) is invisable, multiply a constant for visualization
groundtruth_tensor = labels.unsqueeze(1) * scale # mini_batch*480*640 -> mini_batch*1*480*640
groundtruth_tensor = torch.cat((groundtruth_tensor, groundtruth_tensor, groundtruth_tensor), 1) # change to 3-channel for visualization
groudtruth_images = vutils.make_grid(groundtruth_tensor, nrow=8, padding=10)
writer.add_image('Validation/groudtruth_images', groudtruth_images, accIter['val'])
predicted_tensor = logits.argmax(1).unsqueeze(1)*scale # mini_batch*args.n_class*480*640 -> mini_batch*480*640 -> mini_batch*1*480*640
predicted_tensor = torch.cat((predicted_tensor, predicted_tensor, predicted_tensor), 1) # change to 3-channel for visualization, mini_batch*1*480*640
predicted_images = vutils.make_grid(predicted_tensor, nrow=8, padding=10)
writer.add_image('Validation/predicted_images', predicted_images, accIter['val'])
accIter['val'] += 1
def testing(epo, model, test_loader):
model.eval()
conf_total = np.zeros((args.n_class, args.n_class))
label_list = ["unlabeled", "car", "person", "bike", "curve", "car_stop", "guardrail", "color_cone", "bump"]
testing_results_file = os.path.join(weight_dir, 'testing_results_file.txt')
with torch.no_grad():
for it, (images, labels, names) in enumerate(test_loader):
images = Variable(images).cuda(args.gpu)
labels = Variable(labels).cuda(args.gpu)
logits = model(images)
label = labels.cpu().numpy().squeeze().flatten()
prediction = logits.argmax(1).cpu().numpy().squeeze().flatten() # prediction and label are both 1-d array, size: minibatch*640*480
conf = confusion_matrix(y_true=label, y_pred=prediction, labels=[0,1,2,3,4,5,6,7,8]) # conf is args.n_class*args.n_class matrix, vertical axis: groundtruth, horizontal axis: prediction
conf_total += conf
print('Test: %s, epo %s/%s, iter %s/%s, time %s' % (args.model_name, epo, args.epoch_max, it+1, len(test_loader),
datetime.datetime.now().replace(microsecond=0)-start_datetime))
precision, recall, IoU = compute_results(conf_total)
writer.add_scalar('Test/average_precision',precision.mean(), epo)
writer.add_scalar('Test/average_recall', recall.mean(), epo)
writer.add_scalar('Test/average_IoU', IoU.mean(), epo)
for i in range(len(precision)):
writer.add_scalar("Test(class)/precision_class_%s" % label_list[i], precision[i], epo)
writer.add_scalar("Test(class)/recall_class_%s"% label_list[i], recall[i],epo)
writer.add_scalar('Test(class)/Iou_%s'% label_list[i], IoU[i], epo)
if epo==0:
with open(testing_results_file, 'w') as f:
f.write("# %s, initial lr: %s, batch size: %s, date: %s \n" %(args.model_name, args.lr_start, args.batch_size, datetime.date.today()))
f.write("# epoch: unlabeled, car, person, bike, curve, car_stop, guardrail, color_cone, bump, average(nan_to_num). (Acc %, IoU %)\n")
with open(testing_results_file, 'a') as f:
f.write(str(epo)+': ')
for i in range(len(precision)):
f.write('%0.4f, %0.4f, ' % (100*recall[i], 100*IoU[i]))
f.write('%0.4f, %0.4f\n' % (100*np.mean(np.nan_to_num(recall)), 100*np.mean(np.nan_to_num(IoU))))
print('saving testing results.')
with open(testing_results_file, "r") as file:
writer.add_text('testing_results', file.read().replace('\n', ' \n'), epo)
if __name__ == '__main__':
torch.cuda.set_device(args.gpu)
print("\nthe pytorch version:", torch.__version__)
print("the gpu count:", torch.cuda.device_count())
print("the current used gpu:", torch.cuda.current_device(), '\n')
model = eval(args.model_name)(n_class=args.n_class)
if args.gpu >= 0: model.cuda(args.gpu)
optimizer = torch.optim.SGD(model.parameters(), lr=args.lr_start, momentum=0.9, weight_decay=0.0005)
scheduler = torch.optim.lr_scheduler.ExponentialLR(optimizer, gamma=args.lr_decay, last_epoch=-1)
# preparing folders
if os.path.exists("./runs"):
shutil.rmtree("./runs")
weight_dir = os.path.join("./runs", args.model_name)
os.makedirs(weight_dir)
os.chmod(weight_dir, stat.S_IRWXO) # allow the folder created by docker read, written, and execuated by local machine
writer = SummaryWriter("./runs/tensorboard_log")
os.chmod("./runs/tensorboard_log", stat.S_IRWXO) # allow the folder created by docker read, written, and execuated by local machine
os.chmod("./runs", stat.S_IRWXO)
print('training %s on GPU #%d with pytorch' % (args.model_name, args.gpu))
print('from epoch %d / %s' % (args.epoch_from, args.epoch_max))
print('weight will be saved in: %s' % weight_dir)
train_dataset = MF_dataset(data_dir=args.data_dir, split='train', transform=augmentation_methods)
val_dataset = MF_dataset(data_dir=args.data_dir, split='val')
test_dataset = MF_dataset(data_dir=args.data_dir, split='test')
train_loader = DataLoader(
dataset = train_dataset,
batch_size = args.batch_size,
shuffle = True,
num_workers = args.num_workers,
pin_memory = True,
drop_last = False
)
val_loader = DataLoader(
dataset = val_dataset,
batch_size = args.batch_size,
shuffle = False,
num_workers = args.num_workers,
pin_memory = True,
drop_last = False
)
test_loader = DataLoader(
dataset = test_dataset,
batch_size = args.batch_size,
shuffle = False,
num_workers = args.num_workers,
pin_memory = True,
drop_last = False
)
start_datetime = datetime.datetime.now().replace(microsecond=0)
accIter = {'train': 0, 'val': 0}
for epo in range(args.epoch_from, args.epoch_max):
print('\ntrain %s, epo #%s begin...' % (args.model_name, epo))
#scheduler.step() # if using pytorch 0.4.1, please put this statement here
train(epo, model, train_loader, optimizer)
validation(epo, model, val_loader)
checkpoint_model_file = os.path.join(weight_dir, str(epo) + '.pth')
print('saving check point %s: ' % checkpoint_model_file)
torch.save(model.state_dict(), checkpoint_model_file)
testing(epo, model, test_loader) # testing is just for your reference, you can comment this line during training
scheduler.step() # if using pytorch 1.1 or above, please put this statement here