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fda.py
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fda.py
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"""
@author: Junguang Jiang
@contact: [email protected]
"""
import random
import time
import warnings
import sys
import argparse
from PIL import Image
import numpy as np
import os
import math
import shutil
import torch
import torch.nn as nn
import torch.nn.functional as F
import torch.backends.cudnn as cudnn
from torch.optim import SGD
from torch.optim.lr_scheduler import LambdaLR
from torch.utils.data import DataLoader
sys.path.append('../../..')
from tllib.translation.fourier_transform import FourierTransform
import tllib.vision.models.segmentation as models
import tllib.vision.datasets.segmentation as datasets
import tllib.vision.transforms.segmentation as T
from tllib.vision.transforms import DeNormalizeAndTranspose
from tllib.utils.data import ForeverDataIterator
from tllib.utils.metric import ConfusionMatrix
from tllib.utils.meter import AverageMeter, ProgressMeter, Meter
from tllib.utils.logger import CompleteLogger
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
def robust_entropy(y, ita=1.5, num_classes=19, reduction='mean'):
""" Robust entropy proposed in `FDA: Fourier Domain Adaptation for Semantic Segmentation (CVPR 2020) <https://arxiv.org/abs/2004.05498>`_
Args:
y (tensor): logits output of segmentation model in shape of :math:`(N, C, H, W)`
ita (float, optional): parameters for robust entropy. Default: 1.5
num_classes (int, optional): number of classes. Default: 19
reduction (string, optional): Specifies the reduction to apply to the output:
``'none'`` | ``'mean'``. ``'none'``: no reduction will be applied,
``'mean'``: the sum of the output will be divided by the number of
elements in the output. Default: ``'mean'``
Returns:
Scalar by default. If :attr:`reduction` is ``'none'``, then :math:`(N, )`.
"""
P = F.softmax(y, dim=1)
logP = F.log_softmax(y, dim=1)
PlogP = P * logP
ent = -1.0 * PlogP.sum(dim=1)
ent = ent / math.log(num_classes)
# compute robust entropy
ent = ent ** 2.0 + 1e-8
ent = ent ** ita
if reduction == 'mean':
return ent.mean()
else:
return ent
def main(args: argparse.Namespace):
logger = CompleteLogger(args.log, args.phase)
print(args)
if args.seed is not None:
random.seed(args.seed)
torch.manual_seed(args.seed)
cudnn.deterministic = True
warnings.warn('You have chosen to seed training. '
'This will turn on the CUDNN deterministic setting, '
'which can slow down your training considerably! '
'You may see unexpected behavior when restarting '
'from checkpoints.')
cudnn.benchmark = True
# Data loading code
target_dataset = datasets.__dict__[args.target]
train_target_dataset = target_dataset(
root=args.target_root,
transforms=T.Compose([
T.Resize(image_size=args.train_size),
T.NormalizeAndTranspose(),
]),
)
train_target_loader = DataLoader(train_target_dataset, batch_size=args.batch_size,
shuffle=True, num_workers=args.workers, pin_memory=True, drop_last=True)
val_target_dataset = target_dataset(
root=args.target_root, split='val',
transforms=T.Compose([
T.Resize(image_size=args.test_input_size, label_size=args.test_output_size),
T.NormalizeAndTranspose(),
])
)
val_target_loader = DataLoader(val_target_dataset, batch_size=1, shuffle=False, pin_memory=True)
# collect the absolute paths of all images in the target dataset
target_image_list = train_target_dataset.collect_image_paths()
# build a fourier transform that translate source images to the target style
fourier_transform = T.wrapper(FourierTransform)(target_image_list, os.path.join(logger.root, "amplitudes"),
rebuild=False, beta=args.beta)
source_dataset = datasets.__dict__[args.source]
train_source_dataset = source_dataset(
root=args.source_root,
transforms=T.Compose([
T.Resize((2048, 1024)), # convert source image to the size of the target image before fourier transform
fourier_transform,
T.RandomResizedCrop(size=args.train_size, ratio=args.resize_ratio, scale=(0.5, 1.)),
T.ColorJitter(brightness=0.3, contrast=0.3),
T.RandomHorizontalFlip(),
T.NormalizeAndTranspose(),
]),
)
train_source_loader = DataLoader(train_source_dataset, batch_size=args.batch_size,
shuffle=True, num_workers=args.workers, pin_memory=True, drop_last=True)
train_source_iter = ForeverDataIterator(train_source_loader)
train_target_iter = ForeverDataIterator(train_target_loader)
# create model
model = models.__dict__[args.arch](num_classes=train_source_dataset.num_classes).to(device)
# define optimizer and lr scheduler
optimizer = SGD(model.get_parameters(), lr=args.lr, momentum=args.momentum, weight_decay=args.weight_decay)
lr_scheduler = LambdaLR(optimizer,
lambda x: args.lr * (1. - float(x) / args.epochs / args.iters_per_epoch) ** (args.lr_power))
# optionally resume from a checkpoint
if args.resume:
checkpoint = torch.load(args.resume, map_location='cpu')
model.load_state_dict(checkpoint['model'])
optimizer.load_state_dict(checkpoint['optimizer'])
lr_scheduler.load_state_dict(checkpoint['lr_scheduler'])
args.start_epoch = checkpoint['epoch'] + 1
# define loss function (criterion)
criterion = torch.nn.CrossEntropyLoss(ignore_index=args.ignore_label).to(device)
interp_train = nn.Upsample(size=args.train_size[::-1], mode='bilinear', align_corners=True)
interp_val = nn.Upsample(size=args.test_output_size[::-1], mode='bilinear', align_corners=True)
# define visualization function
decode = train_source_dataset.decode_target
def visualize(image, pred, label, prefix):
"""
Args:
image (tensor): 3 x H x W
pred (tensor): C x H x W
label (tensor): H x W
prefix: prefix of the saving image
"""
image = image.detach().cpu().numpy()
pred = pred.detach().max(dim=0)[1].cpu().numpy()
label = label.cpu().numpy()
for tensor, name in [
(Image.fromarray(np.uint8(DeNormalizeAndTranspose()(image))), "image"),
(decode(label), "label"),
(decode(pred), "pred")
]:
tensor.save(logger.get_image_path("{}_{}.png".format(prefix, name)))
if args.phase == 'test':
confmat = validate(val_target_loader, model, interp_val, criterion, visualize, args)
print(confmat)
return
# start training
best_iou = 0.
for epoch in range(args.start_epoch, args.epochs):
logger.set_epoch(epoch)
print(lr_scheduler.get_lr())
# train for one epoch
train(train_source_iter, train_target_iter, model, interp_train, criterion, optimizer,
lr_scheduler, epoch, visualize if args.debug else None, args)
# evaluate on validation set
confmat = validate(val_target_loader, model, interp_val, criterion, None, args)
print(confmat.format(train_source_dataset.classes))
acc_global, acc, iu = confmat.compute()
# calculate the mean iou over partial classes
indexes = [train_source_dataset.classes.index(name) for name
in train_source_dataset.evaluate_classes]
iu = iu[indexes]
mean_iou = iu.mean()
# remember best acc@1 and save checkpoint
torch.save(
{
'model': model.state_dict(),
'optimizer': optimizer.state_dict(),
'lr_scheduler': lr_scheduler.state_dict(),
'epoch': epoch,
'args': args
}, logger.get_checkpoint_path(epoch)
)
if mean_iou > best_iou:
shutil.copy(logger.get_checkpoint_path(epoch), logger.get_checkpoint_path('best'))
best_iou = max(best_iou, mean_iou)
print("Target: {} Best: {}".format(mean_iou, best_iou))
logger.close()
def train(train_source_iter: ForeverDataIterator, train_target_iter: ForeverDataIterator,
model, interp, criterion, optimizer: SGD,
lr_scheduler: LambdaLR, epoch: int, visualize, args: argparse.Namespace):
batch_time = AverageMeter('Time', ':4.2f')
data_time = AverageMeter('Data', ':3.1f')
losses_s = AverageMeter('Loss (s)', ':3.2f')
losses_t = AverageMeter('Loss (t)', ':3.2f')
losses_entropy_t = AverageMeter('Entropy (t)', ':3.2f')
accuracies_s = Meter('Acc (s)', ':3.2f')
accuracies_t = Meter('Acc (t)', ':3.2f')
iou_s = Meter('IoU (s)', ':3.2f')
iou_t = Meter('IoU (t)', ':3.2f')
confmat_s = ConfusionMatrix(model.num_classes)
confmat_t = ConfusionMatrix(model.num_classes)
progress = ProgressMeter(
args.iters_per_epoch,
[batch_time, data_time, losses_s, losses_t, losses_entropy_t,
accuracies_s, accuracies_t, iou_s, iou_t],
prefix="Epoch: [{}]".format(epoch))
# switch to train mode
model.train()
end = time.time()
for i in range(args.iters_per_epoch):
optimizer.zero_grad()
x_s, label_s = next(train_source_iter)
x_t, label_t = next(train_target_iter)
x_s = x_s.to(device)
label_s = label_s.long().to(device)
x_t = x_t.to(device)
label_t = label_t.long().to(device)
# measure data loading time
data_time.update(time.time() - end)
# compute output
y_s = model(x_s)
pred_s = interp(y_s)
loss_cls_s = criterion(pred_s, label_s)
loss_cls_s.backward()
y_t = model(x_t)
pred_t = interp(y_t)
loss_cls_t = criterion(pred_t, label_t)
loss_entropy_t = robust_entropy(y_t, args.ita)
(args.entropy_weight * loss_entropy_t).backward()
# compute gradient and do SGD step
optimizer.step()
lr_scheduler.step()
# measure accuracy and record loss
losses_s.update(loss_cls_s.item(), x_s.size(0))
losses_t.update(loss_cls_t.item(), x_s.size(0))
losses_entropy_t.update(loss_entropy_t.item(), x_s.size(0))
confmat_s.update(label_s.flatten(), pred_s.argmax(1).flatten())
confmat_t.update(label_t.flatten(), pred_t.argmax(1).flatten())
acc_global_s, acc_s, iu_s = confmat_s.compute()
acc_global_t, acc_t, iu_t = confmat_t.compute()
accuracies_s.update(acc_s.mean().item())
accuracies_t.update(acc_t.mean().item())
iou_s.update(iu_s.mean().item())
iou_t.update(iu_t.mean().item())
# measure elapsed time
batch_time.update(time.time() - end)
end = time.time()
if i % args.print_freq == 0:
progress.display(i)
if visualize is not None:
visualize(x_s[0], pred_s[0], label_s[0], "source_{}".format(i))
visualize(x_t[0], pred_t[0], label_t[0], "target_{}".format(i))
def validate(val_loader: DataLoader, model, interp, criterion, visualize, args: argparse.Namespace):
batch_time = AverageMeter('Time', ':6.3f')
losses = AverageMeter('Loss', ':.4e')
acc = Meter('Acc', ':3.2f')
iou = Meter('IoU', ':3.2f')
progress = ProgressMeter(
len(val_loader),
[batch_time, losses, acc, iou],
prefix='Test: ')
# switch to evaluate mode
model.eval()
confmat = ConfusionMatrix(model.num_classes)
with torch.no_grad():
end = time.time()
for i, (x, label) in enumerate(val_loader):
x = x.to(device)
label = label.long().to(device)
# compute output
output = interp(model(x))
loss = criterion(output, label)
# measure accuracy and record loss
losses.update(loss.item(), x.size(0))
confmat.update(label.flatten(), output.argmax(1).flatten())
acc_global, accs, iu = confmat.compute()
acc.update(accs.mean().item())
iou.update(iu.mean().item())
# measure elapsed time
batch_time.update(time.time() - end)
end = time.time()
if i % args.print_freq == 0:
progress.display(i)
if visualize is not None:
visualize(x[0], output[0], label[0], "val_{}".format(i))
return confmat
if __name__ == '__main__':
architecture_names = sorted(
name for name in models.__dict__
if name.islower() and not name.startswith("__")
and callable(models.__dict__[name])
)
dataset_names = sorted(
name for name in datasets.__dict__
if not name.startswith("__") and callable(datasets.__dict__[name])
)
parser = argparse.ArgumentParser(description='FDA for Segmentation Domain Adaptation')
# dataset parameters
parser.add_argument('source_root', help='root path of the source dataset')
parser.add_argument('target_root', help='root path of the target dataset')
parser.add_argument('-s', '--source', help='source domain(s)')
parser.add_argument('-t', '--target', help='target domain(s)')
parser.add_argument('--resize-ratio', nargs='+', type=float, default=(1.5, 8 / 3.),
help='the resize ratio for the random resize crop')
parser.add_argument('--train-size', nargs='+', type=int, default=(1024, 512),
help='the input and output image size during training')
parser.add_argument('--test-input-size', nargs='+', type=int, default=(1024, 512),
help='the input image size during test')
parser.add_argument('--test-output-size', nargs='+', type=int, default=(2048, 1024),
help='the output image size during test')
# model parameters
parser.add_argument('-a', '--arch', metavar='ARCH', default='deeplabv2_resnet101',
choices=architecture_names,
help='backbone architecture: ' +
' | '.join(architecture_names) +
' (default: deeplabv2_resnet101)')
parser.add_argument("--entropy-weight", type=float, default=0., help="weight for entropy")
parser.add_argument("--ita", type=float, default=2.0, help="ita for robust entropy")
parser.add_argument("--beta", type=int, default=1, help="beta for FDA")
parser.add_argument("--resume", type=str, default=None,
help="Where restore model parameters from.")
# training parameters
parser.add_argument('-b', '--batch-size', default=2, type=int,
metavar='N',
help='mini-batch size (default: 2)')
parser.add_argument('--lr', '--learning-rate', default=2.5e-3, type=float,
metavar='LR', help='initial learning rate', dest='lr')
parser.add_argument("--momentum", type=float, default=0.9, help="Momentum component of the optimiser.")
parser.add_argument("--weight-decay", type=float, default=0.0005, help="Regularisation parameter for L2-loss.")
parser.add_argument("--lr-power", type=float, default=0.9,
help="Decay parameter to compute the learning rate (only for deeplab).")
parser.add_argument('-j', '--workers', default=4, type=int, metavar='N',
help='number of data loading workers (default: 4)')
parser.add_argument('--epochs', default=60, type=int, metavar='N',
help='number of total epochs to run')
parser.add_argument('--start-epoch', default=0, type=int, metavar='N',
help='start epoch')
parser.add_argument('-i', '--iters-per-epoch', default=2500, type=int,
help='Number of iterations per epoch')
parser.add_argument('-p', '--print-freq', default=100, type=int,
metavar='N', help='print frequency (default: 100)')
parser.add_argument('--seed', default=None, type=int,
help='seed for initializing training. ')
parser.add_argument("--ignore-label", type=int, default=255,
help="The index of the label to ignore during the training.")
parser.add_argument("--log", type=str, default='fda',
help="Where to save logs, checkpoints and debugging images.")
parser.add_argument("--phase", type=str, default='train', choices=['train', 'test'],
help="When phase is 'test', only test the model.")
parser.add_argument('--debug', action="store_true",
help='In the debug mode, save images and predictions during training')
args = parser.parse_args()
main(args)