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train.py
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train.py
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import argparse
import time
import csv
import numpy as np
import torch
import torch.backends.cudnn as cudnn
import torch.optim
import torch.utils.data
import custom_transforms
import models
from utils import tensor2array, save_checkpoint, save_path_formatter, log_output_tensorboard
from loss_functions import photometric_reconstruction_loss, explainability_loss, smooth_loss
from loss_functions import compute_depth_errors, compute_pose_errors
from inverse_warp import pose_vec2mat
from logger import TermLogger, AverageMeter
from tensorboardX import SummaryWriter
parser = argparse.ArgumentParser(description='Structure from Motion Learner training on KITTI and CityScapes Dataset',
formatter_class=argparse.ArgumentDefaultsHelpFormatter)
parser.add_argument('data', metavar='DIR',
help='path to dataset')
parser.add_argument('--dataset-format', default='sequential', metavar='STR',
help='dataset format, stacked: stacked frames (from original TensorFlow code) '
'sequential: sequential folders (easier to convert to with a non KITTI/Cityscape dataset')
parser.add_argument('--sequence-length', type=int, metavar='N', help='sequence length for training', default=3)
parser.add_argument('--rotation-mode', type=str, choices=['euler', 'quat'], default='euler',
help='rotation mode for PoseExpnet : euler (yaw,pitch,roll) or quaternion (last 3 coefficients)')
parser.add_argument('--padding-mode', type=str, choices=['zeros', 'border'], default='zeros',
help='padding mode for image warping : this is important for photometric differenciation when going outside target image.'
' zeros will null gradients outside target image.'
' border will only null gradients of the coordinate outside (x or y)')
parser.add_argument('--with-gt', action='store_true', help='use depth ground truth for validation. '
'You need to store it in npy 2D arrays see data/kitti_raw_loader.py for an example')
parser.add_argument('--with-pose', action='store_true', help='use pose ground truth for validation. '
'You need to store it in text files of 12 columns see data/kitti_raw_loader.py for an example '
'Note that for kitti, it is recommend to use odometry train set to test pose')
parser.add_argument('-j', '--workers', default=4, type=int, metavar='N',
help='number of data loading workers')
parser.add_argument('--epochs', default=200, type=int, metavar='N',
help='number of total epochs to run')
parser.add_argument('--epoch-size', default=0, type=int, metavar='N',
help='manual epoch size (will match dataset size if not set)')
parser.add_argument('-b', '--batch-size', default=4, type=int,
metavar='N', help='mini-batch size')
parser.add_argument('--lr', '--learning-rate', default=2e-4, type=float,
metavar='LR', help='initial learning rate')
parser.add_argument('--momentum', default=0.9, type=float, metavar='M',
help='momentum for sgd, alpha parameter for adam')
parser.add_argument('--beta', default=0.999, type=float, metavar='M',
help='beta parameters for adam')
parser.add_argument('--weight-decay', '--wd', default=0, type=float,
metavar='W', help='weight decay')
parser.add_argument('--print-freq', default=10, type=int,
metavar='N', help='print frequency')
parser.add_argument('-e', '--evaluate', dest='evaluate', action='store_true',
help='evaluate model on validation set')
parser.add_argument('--pretrained-disp', dest='pretrained_disp', default=None, metavar='PATH',
help='path to pre-trained dispnet model')
parser.add_argument('--pretrained-exppose', dest='pretrained_exp_pose', default=None, metavar='PATH',
help='path to pre-trained Exp Pose net model')
parser.add_argument('--seed', default=0, type=int, help='seed for random functions, and network initialization')
parser.add_argument('--log-summary', default='progress_log_summary.csv', metavar='PATH',
help='csv where to save per-epoch train and valid stats')
parser.add_argument('--log-full', default='progress_log_full.csv', metavar='PATH',
help='csv where to save per-gradient descent train stats')
parser.add_argument('-p', '--photo-loss-weight', type=float, help='weight for photometric loss', metavar='W', default=1)
parser.add_argument('-m', '--mask-loss-weight', type=float, help='weight for explainabilty mask loss', metavar='W', default=0)
parser.add_argument('-s', '--smooth-loss-weight', type=float, help='weight for disparity smoothness loss', metavar='W', default=0.1)
parser.add_argument('--log-output', action='store_true', help='will log dispnet outputs and warped imgs at validation step')
parser.add_argument('-f', '--training-output-freq', type=int,
help='frequence for outputting dispnet outputs and warped imgs at training for all scales. '
'if 0, will not output',
metavar='N', default=0)
best_error = -1
n_iter = 0
device = torch.device("cuda") if torch.cuda.is_available() else torch.device("cpu")
def main():
global best_error, n_iter, device
args = parser.parse_args()
if args.dataset_format == 'stacked':
from datasets.stacked_sequence_folders import SequenceFolder
elif args.dataset_format == 'sequential':
from datasets.sequence_folders import SequenceFolder
save_path = save_path_formatter(args, parser)
args.save_path = 'checkpoints'/save_path
print('=> will save everything to {}'.format(args.save_path))
args.save_path.makedirs_p()
torch.manual_seed(args.seed)
if args.evaluate:
args.epochs = 0
tb_writer = SummaryWriter(args.save_path)
# Data loading code
normalize = custom_transforms.Normalize(mean=[0.5, 0.5, 0.5],
std=[0.5, 0.5, 0.5])
train_transform = custom_transforms.Compose([
custom_transforms.RandomHorizontalFlip(),
custom_transforms.RandomScaleCrop(),
custom_transforms.ArrayToTensor(),
normalize
])
valid_transform = custom_transforms.Compose([custom_transforms.ArrayToTensor(), normalize])
print("=> fetching scenes in '{}'".format(args.data))
train_set = SequenceFolder(
args.data,
transform=train_transform,
seed=args.seed,
train=True,
sequence_length=args.sequence_length
)
# if no Groundtruth is avalaible, Validation set is the same type as training set to measure photometric loss from warping
if args.with_gt:
if args.with_pose:
from datasets.validation_folders import ValidationSetWithPose
val_set = ValidationSetWithPose(
args.data,
sequence_length=args.sequence_length,
transform=valid_transform)
else:
from datasets.validation_folders import ValidationSet
val_set = ValidationSet(
args.data,
transform=valid_transform
)
else:
val_set = SequenceFolder(
args.data,
transform=valid_transform,
seed=args.seed,
train=False,
sequence_length=args.sequence_length,
)
print('{} samples found in {} train scenes'.format(len(train_set), len(train_set.scenes)))
print('{} samples found in {} valid scenes'.format(len(val_set), len(val_set.scenes)))
train_loader = torch.utils.data.DataLoader(
train_set, batch_size=args.batch_size, shuffle=True,
num_workers=args.workers, pin_memory=True)
val_loader = torch.utils.data.DataLoader(
val_set, batch_size=args.batch_size, shuffle=False,
num_workers=args.workers, pin_memory=True)
if args.epoch_size == 0:
args.epoch_size = len(train_loader)
# create model
print("=> creating model")
disp_net = models.DispNetS().to(device)
output_exp = args.mask_loss_weight > 0
if not output_exp:
print("=> no mask loss, PoseExpnet will only output pose")
pose_exp_net = models.PoseExpNet(nb_ref_imgs=args.sequence_length - 1, output_exp=args.mask_loss_weight > 0).to(device)
if args.pretrained_exp_pose:
print("=> using pre-trained weights for explainabilty and pose net")
weights = torch.load(args.pretrained_exp_pose)
pose_exp_net.load_state_dict(weights['state_dict'], strict=False)
else:
pose_exp_net.init_weights()
if args.pretrained_disp:
print("=> using pre-trained weights for Dispnet")
weights = torch.load(args.pretrained_disp)
disp_net.load_state_dict(weights['state_dict'])
else:
disp_net.init_weights()
cudnn.benchmark = True
disp_net = torch.nn.DataParallel(disp_net)
pose_exp_net = torch.nn.DataParallel(pose_exp_net)
print('=> setting adam solver')
optim_params = [
{'params': disp_net.parameters(), 'lr': args.lr},
{'params': pose_exp_net.parameters(), 'lr': args.lr}
]
optimizer = torch.optim.Adam(optim_params,
betas=(args.momentum, args.beta),
weight_decay=args.weight_decay)
with open(args.save_path/args.log_summary, 'w') as csvfile:
writer = csv.writer(csvfile, delimiter='\t')
writer.writerow(['train_loss', 'validation_loss'])
with open(args.save_path/args.log_full, 'w') as csvfile:
writer = csv.writer(csvfile, delimiter='\t')
writer.writerow(['train_loss', 'photo_loss', 'explainability_loss', 'smooth_loss'])
logger = TermLogger(n_epochs=args.epochs, train_size=min(len(train_loader), args.epoch_size), valid_size=len(val_loader))
logger.epoch_bar.start()
if args.pretrained_disp or args.evaluate:
logger.reset_valid_bar()
if args.with_gt and args.with_pose:
errors, error_names = validate_with_gt_pose(args, val_loader, disp_net, pose_exp_net, 0, logger, tb_writer)
elif args.with_gt:
errors, error_names = validate_with_gt(args, val_loader, disp_net, 0, logger, tb_writer)
else:
errors, error_names = validate_without_gt(args, val_loader, disp_net, pose_exp_net, 0, logger, tb_writer)
for error, name in zip(errors, error_names):
tb_writer.add_scalar(name, error, 0)
error_string = ', '.join('{} : {:.3f}'.format(name, error) for name, error in zip(error_names[2:9], errors[2:9]))
logger.valid_writer.write(' * Avg {}'.format(error_string))
for epoch in range(args.epochs):
logger.epoch_bar.update(epoch)
# train for one epoch
logger.reset_train_bar()
train_loss = train(args, train_loader, disp_net, pose_exp_net, optimizer, args.epoch_size, logger, tb_writer)
logger.train_writer.write(' * Avg Loss : {:.3f}'.format(train_loss))
# evaluate on validation set
logger.reset_valid_bar()
if args.with_gt and args.with_pose:
errors, error_names = validate_with_gt_pose(args, val_loader, disp_net, pose_exp_net, epoch, logger, tb_writer)
elif args.with_gt:
errors, error_names = validate_with_gt(args, val_loader, disp_net, epoch, logger, tb_writer)
else:
errors, error_names = validate_without_gt(args, val_loader, disp_net, pose_exp_net, epoch, logger, tb_writer)
error_string = ', '.join('{} : {:.3f}'.format(name, error) for name, error in zip(error_names, errors))
logger.valid_writer.write(' * Avg {}'.format(error_string))
for error, name in zip(errors, error_names):
tb_writer.add_scalar(name, error, epoch)
# Up to you to chose the most relevant error to measure your model's performance, careful some measures are to maximize (such as a1,a2,a3)
decisive_error = errors[1]
if best_error < 0:
best_error = decisive_error
# remember lowest error and save checkpoint
is_best = decisive_error < best_error
best_error = min(best_error, decisive_error)
save_checkpoint(
args.save_path, {
'epoch': epoch + 1,
'state_dict': disp_net.module.state_dict()
}, {
'epoch': epoch + 1,
'state_dict': pose_exp_net.module.state_dict()
},
is_best)
with open(args.save_path/args.log_summary, 'a') as csvfile:
writer = csv.writer(csvfile, delimiter='\t')
writer.writerow([train_loss, decisive_error])
logger.epoch_bar.finish()
def train(args, train_loader, disp_net, pose_exp_net, optimizer, epoch_size, logger, tb_writer):
global n_iter, device
batch_time = AverageMeter()
data_time = AverageMeter()
losses = AverageMeter(precision=4)
w1, w2, w3 = args.photo_loss_weight, args.mask_loss_weight, args.smooth_loss_weight
# switch to train mode
disp_net.train()
pose_exp_net.train()
end = time.time()
logger.train_bar.update(0)
for i, (tgt_img, ref_imgs, intrinsics, intrinsics_inv) in enumerate(train_loader):
log_losses = i > 0 and n_iter % args.print_freq == 0
log_output = args.training_output_freq > 0 and n_iter % args.training_output_freq == 0
# measure data loading time
data_time.update(time.time() - end)
tgt_img = tgt_img.to(device)
ref_imgs = [img.to(device) for img in ref_imgs]
intrinsics = intrinsics.to(device)
# compute output
disparities = disp_net(tgt_img)
depth = [1/disp for disp in disparities]
explainability_mask, pose = pose_exp_net(tgt_img, ref_imgs)
loss_1, warped, diff = photometric_reconstruction_loss(tgt_img, ref_imgs, intrinsics,
depth, explainability_mask, pose,
args.rotation_mode, args.padding_mode)
if w2 > 0:
loss_2 = explainability_loss(explainability_mask)
else:
loss_2 = 0
loss_3 = smooth_loss(depth)
loss = w1*loss_1 + w2*loss_2 + w3*loss_3
if log_losses:
tb_writer.add_scalar('photometric_error', loss_1.item(), n_iter)
if w2 > 0:
tb_writer.add_scalar('explanability_loss', loss_2.item(), n_iter)
tb_writer.add_scalar('disparity_smoothness_loss', loss_3.item(), n_iter)
tb_writer.add_scalar('total_loss', loss.item(), n_iter)
if log_output:
tb_writer.add_image('train Input', tensor2array(tgt_img[0]), n_iter)
for k, scaled_maps in enumerate(zip(depth, disparities, warped, diff, explainability_mask)):
log_output_tensorboard(tb_writer, "train", 0, " {}".format(k), n_iter, *scaled_maps)
# record loss and EPE
losses.update(loss.item(), args.batch_size)
# compute gradient and do Adam step
optimizer.zero_grad()
loss.backward()
optimizer.step()
# measure elapsed time
batch_time.update(time.time() - end)
end = time.time()
with open(args.save_path/args.log_full, 'a') as csvfile:
writer = csv.writer(csvfile, delimiter='\t')
writer.writerow([loss.item(), loss_1.item(), loss_2.item() if w2 > 0 else 0, loss_3.item()])
logger.train_bar.update(i+1)
if i % args.print_freq == 0:
logger.train_writer.write('Train: Time {} Data {} Loss {}'.format(batch_time, data_time, losses))
if i >= epoch_size - 1:
break
n_iter += 1
return losses.avg[0]
@torch.no_grad()
def validate_without_gt(args, val_loader, disp_net, pose_exp_net, epoch, logger, tb_writer, sample_nb_to_log=3):
global device
batch_time = AverageMeter()
losses = AverageMeter(i=3, precision=4)
log_outputs = sample_nb_to_log > 0
# Output the logs throughout the whole dataset
batches_to_log = list(np.linspace(0, len(val_loader), sample_nb_to_log).astype(int))
w1, w2, w3 = args.photo_loss_weight, args.mask_loss_weight, args.smooth_loss_weight
poses = np.zeros(((len(val_loader)-1) * args.batch_size * (args.sequence_length-1), 6))
disp_values = np.zeros(((len(val_loader)-1) * args.batch_size * 3))
# switch to evaluate mode
disp_net.eval()
pose_exp_net.eval()
end = time.time()
logger.valid_bar.update(0)
for i, (tgt_img, ref_imgs, intrinsics, intrinsics_inv) in enumerate(val_loader):
tgt_img = tgt_img.to(device)
ref_imgs = [img.to(device) for img in ref_imgs]
intrinsics = intrinsics.to(device)
intrinsics_inv = intrinsics_inv.to(device)
# compute output
disp = disp_net(tgt_img)
depth = 1/disp
explainability_mask, pose = pose_exp_net(tgt_img, ref_imgs)
loss_1, warped, diff = photometric_reconstruction_loss(tgt_img, ref_imgs,
intrinsics, depth,
explainability_mask, pose,
args.rotation_mode, args.padding_mode)
loss_1 = loss_1.item()
if w2 > 0:
loss_2 = explainability_loss(explainability_mask).item()
else:
loss_2 = 0
loss_3 = smooth_loss(depth).item()
if log_outputs and i in batches_to_log: # log first output of wanted batches
index = batches_to_log.index(i)
if epoch == 0:
for j, ref in enumerate(ref_imgs):
tb_writer.add_image('val Input {}/{}'.format(j, index), tensor2array(tgt_img[0]), 0)
tb_writer.add_image('val Input {}/{}'.format(j, index), tensor2array(ref[0]), 1)
log_output_tensorboard(tb_writer, 'val', index, '', epoch, 1./disp, disp, warped[0], diff[0], explainability_mask)
if log_outputs and i < len(val_loader)-1:
step = args.batch_size*(args.sequence_length-1)
poses[i * step:(i+1) * step] = pose.cpu().view(-1, 6).numpy()
step = args.batch_size * 3
disp_unraveled = disp.cpu().view(args.batch_size, -1)
disp_values[i * step:(i+1) * step] = torch.cat([disp_unraveled.min(-1)[0],
disp_unraveled.median(-1)[0],
disp_unraveled.max(-1)[0]]).numpy()
loss = w1*loss_1 + w2*loss_2 + w3*loss_3
losses.update([loss, loss_1, loss_2])
# measure elapsed time
batch_time.update(time.time() - end)
end = time.time()
logger.valid_bar.update(i+1)
if i % args.print_freq == 0:
logger.valid_writer.write('valid: Time {} Loss {}'.format(batch_time, losses))
if log_outputs:
prefix = 'valid poses'
coeffs_names = ['tx', 'ty', 'tz']
if args.rotation_mode == 'euler':
coeffs_names.extend(['rx', 'ry', 'rz'])
elif args.rotation_mode == 'quat':
coeffs_names.extend(['qx', 'qy', 'qz'])
for i in range(poses.shape[1]):
tb_writer.add_histogram('{} {}'.format(prefix, coeffs_names[i]), poses[:, i], epoch)
tb_writer.add_histogram('disp_values', disp_values, epoch)
logger.valid_bar.update(len(val_loader))
return losses.avg, ['Validation Total loss', 'Validation Photo loss', 'Validation Exp loss']
@torch.no_grad()
def validate_with_gt_pose(args, val_loader, disp_net, pose_exp_net, epoch, logger, tb_writer, sample_nb_to_log=3):
global device
batch_time = AverageMeter()
depth_error_names = ['abs_diff', 'abs_rel', 'sq_rel', 'a1', 'a2', 'a3']
depth_errors = AverageMeter(i=len(depth_error_names), precision=4)
pose_error_names = ['ATE', 'RTE']
pose_errors = AverageMeter(i=2, precision=4)
log_outputs = sample_nb_to_log > 0
# Output the logs throughout the whole dataset
batches_to_log = list(np.linspace(0, len(val_loader), sample_nb_to_log).astype(int))
poses_values = np.zeros(((len(val_loader)-1) * args.batch_size * (args.sequence_length-1), 6))
disp_values = np.zeros(((len(val_loader)-1) * args.batch_size * 3))
# switch to evaluate mode
disp_net.eval()
pose_exp_net.eval()
end = time.time()
logger.valid_bar.update(0)
for i, (tgt_img, ref_imgs, gt_depth, gt_poses) in enumerate(val_loader):
tgt_img = tgt_img.to(device)
gt_depth = gt_depth.to(device)
gt_poses = gt_poses.to(device)
ref_imgs = [img.to(device) for img in ref_imgs]
b = tgt_img.shape[0]
# compute output
output_disp = disp_net(tgt_img)
output_depth = 1/output_disp
explainability_mask, output_poses = pose_exp_net(tgt_img, ref_imgs)
reordered_output_poses = torch.cat([output_poses[:, :gt_poses.shape[1]//2],
torch.zeros(b, 1, 6).to(output_poses),
output_poses[:, gt_poses.shape[1]//2:]], dim=1)
# pose_vec2mat only takes B, 6 tensors, so we simulate a batch dimension of B * seq_length
unravelled_poses = reordered_output_poses.reshape(-1, 6)
unravelled_matrices = pose_vec2mat(unravelled_poses, rotation_mode=args.rotation_mode)
inv_transform_matrices = unravelled_matrices.reshape(b, -1, 3, 4)
rot_matrices = inv_transform_matrices[..., :3].transpose(-2, -1)
tr_vectors = -rot_matrices @ inv_transform_matrices[..., -1:]
transform_matrices = torch.cat([rot_matrices, tr_vectors], axis=-1)
first_inv_transform = inv_transform_matrices.reshape(b, -1, 3, 4)[:, :1]
final_poses = first_inv_transform[..., :3] @ transform_matrices
final_poses[..., -1:] += first_inv_transform[..., -1:]
final_poses = final_poses.reshape(b, -1, 3, 4)
if log_outputs and i in batches_to_log: # log first output of wanted batches
index = batches_to_log.index(i)
if epoch == 0:
for j, ref in enumerate(ref_imgs):
tb_writer.add_image('val Input {}/{}'.format(j, index), tensor2array(tgt_img[0]), 0)
tb_writer.add_image('val Input {}/{}'.format(j, index), tensor2array(ref[0]), 1)
log_output_tensorboard(tb_writer, 'val', index, '', epoch, output_depth, output_disp, None, None, explainability_mask)
if log_outputs and i < len(val_loader)-1:
step = args.batch_size*(args.sequence_length-1)
poses_values[i * step:(i+1) * step] = output_poses.cpu().view(-1, 6).numpy()
step = args.batch_size * 3
disp_unraveled = output_disp.cpu().view(args.batch_size, -1)
disp_values[i * step:(i+1) * step] = torch.cat([disp_unraveled.min(-1)[0],
disp_unraveled.median(-1)[0],
disp_unraveled.max(-1)[0]]).numpy()
depth_errors.update(compute_depth_errors(gt_depth, output_depth[:, 0]))
pose_errors.update(compute_pose_errors(gt_poses, final_poses))
# measure elapsed time
batch_time.update(time.time() - end)
end = time.time()
logger.valid_bar.update(i+1)
if i % args.print_freq == 0:
logger.valid_writer.write(
'valid: Time {} Abs Error {:.4f} ({:.4f}), ATE {:.4f} ({:.4f})'.format(batch_time,
depth_errors.val[0],
depth_errors.avg[0],
pose_errors.val[0],
pose_errors.avg[0]))
if log_outputs:
prefix = 'valid poses'
coeffs_names = ['tx', 'ty', 'tz']
if args.rotation_mode == 'euler':
coeffs_names.extend(['rx', 'ry', 'rz'])
elif args.rotation_mode == 'quat':
coeffs_names.extend(['qx', 'qy', 'qz'])
for i in range(poses_values.shape[1]):
tb_writer.add_histogram('{} {}'.format(prefix, coeffs_names[i]), poses_values[:, i], epoch)
tb_writer.add_histogram('disp_values', disp_values, epoch)
logger.valid_bar.update(len(val_loader))
return depth_errors.avg + pose_errors.avg, depth_error_names + pose_error_names
@torch.no_grad()
def validate_with_gt(args, val_loader, disp_net, epoch, logger, tb_writer, sample_nb_to_log=3):
global device
batch_time = AverageMeter()
error_names = ['abs_diff', 'abs_rel', 'sq_rel', 'a1', 'a2', 'a3']
errors = AverageMeter(i=len(error_names))
log_outputs = sample_nb_to_log > 0
# Output the logs throughout the whole dataset
batches_to_log = list(np.linspace(0, len(val_loader)-1, sample_nb_to_log).astype(int))
# switch to evaluate mode
disp_net.eval()
end = time.time()
logger.valid_bar.update(0)
for i, (tgt_img, depth) in enumerate(val_loader):
tgt_img = tgt_img.to(device)
depth = depth.to(device)
# compute output
output_disp = disp_net(tgt_img)
output_depth = 1/output_disp[:, 0]
if log_outputs and i in batches_to_log:
index = batches_to_log.index(i)
if epoch == 0:
tb_writer.add_image('val Input/{}'.format(index), tensor2array(tgt_img[0]), 0)
depth_to_show = depth[0]
tb_writer.add_image('val target Depth Normalized/{}'.format(index),
tensor2array(depth_to_show, max_value=None),
epoch)
depth_to_show[depth_to_show == 0] = 1000
disp_to_show = (1/depth_to_show).clamp(0, 10)
tb_writer.add_image('val target Disparity Normalized/{}'.format(index),
tensor2array(disp_to_show, max_value=None, colormap='magma'),
epoch)
tb_writer.add_image('val Dispnet Output Normalized/{}'.format(index),
tensor2array(output_disp[0], max_value=None, colormap='magma'),
epoch)
tb_writer.add_image('val Depth Output Normalized/{}'.format(index),
tensor2array(output_depth[0], max_value=None),
epoch)
errors.update(compute_depth_errors(depth, output_depth))
# measure elapsed time
batch_time.update(time.time() - end)
end = time.time()
logger.valid_bar.update(i+1)
if i % args.print_freq == 0:
logger.valid_writer.write('valid: Time {} Abs Error {:.4f} ({:.4f})'.format(batch_time, errors.val[0], errors.avg[0]))
logger.valid_bar.update(len(val_loader))
return errors.avg, error_names
if __name__ == '__main__':
main()