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image_source.py
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image_source.py
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import argparse
import os, sys
import os.path as osp
import torchvision
import numpy as np
import torch
import torch.nn as nn
import torch.optim as optim
from torchvision import transforms
import network, loss
from torch.utils.data import DataLoader
from data_list import ImageList
import random, pdb, math, copy
from tqdm import tqdm
from loss import CrossEntropyLabelSmooth
from scipy.spatial.distance import cdist
from sklearn.metrics import confusion_matrix
from sklearn.cluster import KMeans
def op_copy(optimizer):
for param_group in optimizer.param_groups:
param_group['lr0'] = param_group['lr']
return optimizer
def lr_scheduler(optimizer, iter_num, max_iter, gamma=10, power=0.75):
decay = (1 + gamma * iter_num / max_iter) ** (-power)
for param_group in optimizer.param_groups:
param_group['lr'] = param_group['lr0'] * decay
param_group['weight_decay'] = 1e-3
param_group['momentum'] = 0.9
param_group['nesterov'] = True
return optimizer
def image_train(resize_size=256, crop_size=224, alexnet=False):
if not alexnet:
normalize = transforms.Normalize(mean=[0.485, 0.456, 0.406],
std=[0.229, 0.224, 0.225])
else:
normalize = Normalize(meanfile='./ilsvrc_2012_mean.npy')
return transforms.Compose([
transforms.Resize((resize_size, resize_size)),
transforms.RandomCrop(crop_size),
transforms.RandomHorizontalFlip(),
transforms.ToTensor(),
normalize
])
def image_test(resize_size=256, crop_size=224, alexnet=False):
if not alexnet:
normalize = transforms.Normalize(mean=[0.485, 0.456, 0.406],
std=[0.229, 0.224, 0.225])
else:
normalize = Normalize(meanfile='./ilsvrc_2012_mean.npy')
return transforms.Compose([
transforms.Resize((resize_size, resize_size)),
transforms.CenterCrop(crop_size),
transforms.ToTensor(),
normalize
])
def data_load(args):
## prepare data
dsets = {}
dset_loaders = {}
train_bs = args.batch_size
# print(args.s_dset_path)
txt_src = open(args.s_dset_path).readlines()
txt_test = open(args.test_dset_path).readlines()
if not args.da == 'uda':
label_map_s = {}
for i in range(len(args.src_classes)):
label_map_s[args.src_classes[i]] = i
new_src = []
for i in range(len(txt_src)):
rec = txt_src[i]
reci = rec.strip().split(' ')
if int(reci[1]) in args.src_classes:
line = reci[0] + ' ' + str(label_map_s[int(reci[1])]) + '\n'
new_src.append(line)
txt_src = new_src.copy()
new_tar = []
for i in range(len(txt_test)):
rec = txt_test[i]
reci = rec.strip().split(' ')
if int(reci[1]) in args.tar_classes:
if int(reci[1]) in args.src_classes:
line = reci[0] + ' ' + str(label_map_s[int(reci[1])]) + '\n'
new_tar.append(line)
else:
line = reci[0] + ' ' + str(len(label_map_s)) + '\n'
new_tar.append(line)
txt_test = new_tar.copy()
if args.trte == "val":
dsize = len(txt_src)
tr_size = int(0.9*dsize)
# print(dsize, tr_size, dsize - tr_size)
tr_txt, te_txt = torch.utils.data.random_split(txt_src, [tr_size, dsize - tr_size])
else:
dsize = len(txt_src)
tr_size = int(0.9*dsize)
_, te_txt = torch.utils.data.random_split(txt_src, [tr_size, dsize - tr_size])
tr_txt = txt_src
dsets["source_tr"] = ImageList(tr_txt, transform=image_train())
dset_loaders["source_tr"] = DataLoader(dsets["source_tr"], batch_size=train_bs, shuffle=True, num_workers=args.worker, drop_last=False)
dsets["source_te"] = ImageList(te_txt, transform=image_test())
dset_loaders["source_te"] = DataLoader(dsets["source_te"], batch_size=train_bs, shuffle=True, num_workers=args.worker, drop_last=False)
dsets["test"] = ImageList(txt_test, transform=image_test())
dset_loaders["test"] = DataLoader(dsets["test"], batch_size=train_bs*2, shuffle=True, num_workers=args.worker, drop_last=False)
return dset_loaders
def cal_acc(loader, netF, netB, netC, flag=False):
start_test = True
with torch.no_grad():
iter_test = iter(loader)
for i in range(len(loader)):
data = iter_test.next()
inputs = data[0]
labels = data[1]
inputs = inputs.cuda()
outputs = netC(netB(netF(inputs)))
if start_test:
all_output = outputs.float().cpu()
all_label = labels.float()
start_test = False
else:
all_output = torch.cat((all_output, outputs.float().cpu()), 0)
all_label = torch.cat((all_label, labels.float()), 0)
all_output = nn.Softmax(dim=1)(all_output)
_, predict = torch.max(all_output, 1)
accuracy = torch.sum(torch.squeeze(predict).float() == all_label).item() / float(all_label.size()[0])
mean_ent = torch.mean(loss.Entropy(all_output)).cpu().data.item()
if flag:
matrix = confusion_matrix(all_label, torch.squeeze(predict).float())
acc = matrix.diagonal()/matrix.sum(axis=1) * 100
aacc = acc.mean()
aa = [str(np.round(i, 2)) for i in acc]
acc = ' '.join(aa)
return aacc, acc
else:
return accuracy*100, mean_ent
def cal_acc_oda(loader, netF, netB, netC):
start_test = True
with torch.no_grad():
iter_test = iter(loader)
for i in range(len(loader)):
data = iter_test.next()
inputs = data[0]
labels = data[1]
inputs = inputs.cuda()
outputs = netC(netB(netF(inputs)))
if start_test:
all_output = outputs.float().cpu()
all_label = labels.float()
start_test = False
else:
all_output = torch.cat((all_output, outputs.float().cpu()), 0)
all_label = torch.cat((all_label, labels.float()), 0)
all_output = nn.Softmax(dim=1)(all_output)
_, predict = torch.max(all_output, 1)
ent = torch.sum(-all_output * torch.log(all_output + args.epsilon), dim=1) / np.log(args.class_num)
ent = ent.float().cpu()
initc = np.array([[0], [1]])
kmeans = KMeans(n_clusters=2, random_state=0, init=initc, n_init=1).fit(ent.reshape(-1,1))
threshold = (kmeans.cluster_centers_).mean()
predict[ent>threshold] = args.class_num
matrix = confusion_matrix(all_label, torch.squeeze(predict).float())
matrix = matrix[np.unique(all_label).astype(int),:]
acc = matrix.diagonal()/matrix.sum(axis=1) * 100
unknown_acc = acc[-1:].item()
return np.mean(acc[:-1]), np.mean(acc), unknown_acc
# return np.mean(acc), np.mean(acc[:-1])
def train_source(args):
dset_loaders = data_load(args)
## set base network
if args.net[0:3] == 'res':
netF = network.ResBase(res_name=args.net,se=args.se,nl=args.nl).cuda()
elif args.net[0:3] == 'vgg':
netF = network.VGGBase(vgg_name=args.net).cuda()
elif args.net == 'vit':
netF = network.ViT().cuda()
### test model paremet size
# model=network.ResBase(res_name=args.net)
# num_params = sum([np.prod(p.size()) for p in model.parameters()])
# print("Total number of parameters: {}".format(num_params))
#
# num_params_update = sum([np.prod(p.shape) for p in model.parameters() if p.requires_grad])
# print("Total number of learning parameters: {}".format(num_params_update))
netB = network.feat_bootleneck(type=args.classifier, feature_dim=netF.in_features, bottleneck_dim=args.bottleneck).cuda()
netC = network.feat_classifier(type=args.layer, class_num = args.class_num, bottleneck_dim=args.bottleneck).cuda()
param_group = []
learning_rate = args.lr
for k, v in netF.named_parameters():
param_group += [{'params': v, 'lr': learning_rate*0.1}]
for k, v in netB.named_parameters():
param_group += [{'params': v, 'lr': learning_rate}]
for k, v in netC.named_parameters():
param_group += [{'params': v, 'lr': learning_rate}]
optimizer = optim.SGD(param_group)
optimizer = op_copy(optimizer)
acc_init = 0
max_iter = args.max_epoch * len(dset_loaders["source_tr"])
interval_iter = max_iter // 10
iter_num = 0
netF.train()
netB.train()
netC.train()
while iter_num < max_iter:
try:
inputs_source, labels_source = iter_source.next()
except:
iter_source = iter(dset_loaders["source_tr"])
inputs_source, labels_source = iter_source.next()
if inputs_source.size(0) == 1:
continue
iter_num += 1
lr_scheduler(optimizer, iter_num=iter_num, max_iter=max_iter)
inputs_source, labels_source = inputs_source.cuda(), labels_source.cuda()
outputs_source = netC(netB(netF(inputs_source)))
classifier_loss = CrossEntropyLabelSmooth(num_classes=args.class_num, epsilon=args.smooth)(outputs_source, labels_source)
optimizer.zero_grad()
classifier_loss.backward()
optimizer.step()
if iter_num % interval_iter == 0 or iter_num == max_iter:
netF.eval()
netB.eval()
netC.eval()
if args.dset=='VISDA-C':
acc_s_te, acc_list = cal_acc(dset_loaders['source_te'], netF, netB, netC, True)
log_str = 'Task: {}, Iter:{}/{}; Accuracy = {:.2f}%'.format(args.name_src, iter_num, max_iter, acc_s_te) + '\n' + acc_list
else:
acc_s_te, _ = cal_acc(dset_loaders['source_te'], netF, netB, netC, False)
log_str = 'Task: {}, Iter:{}/{}; Accuracy = {:.2f}%'.format(args.name_src, iter_num, max_iter, acc_s_te)
args.out_file.write(log_str + '\n')
args.out_file.flush()
print(log_str+'\n')
if acc_s_te >= acc_init:
acc_init = acc_s_te
best_netF = netF.state_dict()
best_netB = netB.state_dict()
best_netC = netC.state_dict()
netF.train()
netB.train()
netC.train()
torch.save(best_netF, osp.join(args.output_dir_src, "source_F.pt"))
torch.save(best_netB, osp.join(args.output_dir_src, "source_B.pt"))
torch.save(best_netC, osp.join(args.output_dir_src, "source_C.pt"))
return netF, netB, netC
def test_target(args):
dset_loaders = data_load(args)
## set base network
if args.net[0:3] == 'res':
netF = network.ResBase(res_name=args.net).cuda()
elif args.net[0:3] == 'vgg':
netF = network.VGGBase(vgg_name=args.net).cuda()
else:
netF = network.ViT().cuda()
netB = network.feat_bootleneck(type=args.classifier, feature_dim=netF.in_features, bottleneck_dim=args.bottleneck).cuda()
netC = network.feat_classifier(type=args.layer, class_num = args.class_num, bottleneck_dim=args.bottleneck).cuda()
args.modelpath = args.output_dir_src + '/source_F.pt'
netF.load_state_dict(torch.load(args.modelpath))
args.modelpath = args.output_dir_src + '/source_B.pt'
netB.load_state_dict(torch.load(args.modelpath))
args.modelpath = args.output_dir_src + '/source_C.pt'
netC.load_state_dict(torch.load(args.modelpath))
netF.eval()
netB.eval()
netC.eval()
if args.da == 'oda':
acc_os1, acc_os2, acc_unknown = cal_acc_oda(dset_loaders['test'], netF, netB, netC)
log_str = '\nTraining: {}, Task: {}, Accuracy = {:.2f}% / {:.2f}% / {:.2f}%'.format(args.trte, args.name, acc_os2, acc_os1, acc_unknown)
else:
if args.dset=='VISDA-C':
acc, acc_list = cal_acc(dset_loaders['test'], netF, netB, netC, True)
log_str = '\nTraining: {}, Task: {}, Accuracy = {:.2f}%'.format(args.trte, args.name, acc) + '\n' + acc_list
else:
acc, _ = cal_acc(dset_loaders['test'], netF, netB, netC, False)
log_str = '\nTraining: {}, Task: {}, Accuracy = {:.2f}%'.format(args.trte, args.name, acc)
args.out_file.write(log_str)
args.out_file.flush()
print(log_str)
def print_args(args):
s = "==========================================\n"
for arg, content in args.__dict__.items():
s += "{}:{}\n".format(arg, content)
return s
if __name__ == "__main__":
parser = argparse.ArgumentParser(description='SHOT')
parser.add_argument('--gpu_id', type=str, nargs='?', default='0', help="device id to run")
parser.add_argument('--s', type=int, default=0, help="source")
parser.add_argument('--t', type=int, default=1, help="target")
parser.add_argument('--max_epoch', type=int, default=20, help="max iterations")
parser.add_argument('--batch_size', type=int, default=64, help="batch_size")
parser.add_argument('--worker', type=int, default=4, help="number of workers")
parser.add_argument('--dset', type=str, default='office-home', choices=['VISDA-C', 'office', 'office-home', 'office-caltech'])
parser.add_argument('--lr', type=float, default=1e-2, help="learning rate")
parser.add_argument('--net', type=str, default='vit', help="vgg16, resnet50, resnet101")
parser.add_argument('--seed', type=int, default=2020, help="random seed")
parser.add_argument('--bottleneck', type=int, default=256)
parser.add_argument('--epsilon', type=float, default=1e-5)
parser.add_argument('--layer', type=str, default="wn", choices=["linear", "wn"])
parser.add_argument('--classifier', type=str, default="bn", choices=["ori", "bn"])
parser.add_argument('--smooth', type=float, default=0.1)
parser.add_argument('--output', type=str, default='san')
parser.add_argument('--da', type=str, default='uda', choices=['uda', 'pda', 'oda'])
parser.add_argument('--trte', type=str, default='val', choices=['full', 'val'])
parser.add_argument('--bsp', type=bool, default=False)
parser.add_argument('--se', type=bool, default=False)
parser.add_argument('--nl', type=bool, default=False)
args = parser.parse_args()
if args.dset == 'office-home':
names = ['Art', 'Clipart', 'Product', 'RealWorld']
args.class_num = 65
if args.dset == 'office':
names = ['amazon', 'dslr', 'webcam']
args.class_num = 31
if args.dset == 'VISDA-C':
names = ['train', 'validation']
args.class_num = 12
if args.dset == 'office-caltech':
names = ['amazon', 'caltech', 'dslr', 'webcam']
args.class_num = 10
os.environ["CUDA_VISIBLE_DEVICES"] = args.gpu_id
SEED = args.seed
torch.manual_seed(SEED)
torch.cuda.manual_seed(SEED)
np.random.seed(SEED)
random.seed(SEED)
# torch.backends.cudnn.deterministic = True
folder = './data/'
args.s_dset_path = folder + args.dset + '/' + names[args.s] + '_list.txt'
args.test_dset_path = folder + args.dset + '/' + names[args.t] + '_list.txt'
if args.dset == 'office-home':
if args.da == 'pda':
args.class_num = 65
args.src_classes = [i for i in range(65)]
args.tar_classes = [i for i in range(25)]
if args.da == 'oda':
args.class_num = 25
args.src_classes = [i for i in range(25)]
args.tar_classes = [i for i in range(65)]
args.output_dir_src = osp.join(args.output, args.da, args.dset, names[args.s][0].upper())
args.name_src = names[args.s][0].upper()
if not osp.exists(args.output_dir_src):
os.system('mkdir -p ' + args.output_dir_src)
if not osp.exists(args.output_dir_src):
os.mkdir(args.output_dir_src)
args.out_file = open(osp.join(args.output_dir_src, 'log.txt'), 'w')
args.out_file.write(print_args(args)+'\n')
args.out_file.flush()
train_source(args)
args.out_file = open(osp.join(args.output_dir_src, 'log_test.txt'), 'w')
for i in range(len(names)):
if i == args.s:
continue
args.t = i
args.name = names[args.s][0].upper() + names[args.t][0].upper()
folder = './data/'
args.s_dset_path = folder + args.dset + '/' + names[args.s] + '_list.txt'
args.test_dset_path = folder + args.dset + '/' + names[args.t] + '_list.txt'
if args.dset == 'office-home':
if args.da == 'pda':
args.class_num = 65
args.src_classes = [i for i in range(65)]
args.tar_classes = [i for i in range(25)]
if args.da == 'oda':
args.class_num = 25
args.src_classes = [i for i in range(25)]
args.tar_classes = [i for i in range(65)]
test_target(args)