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Train_cifar.py
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Train_cifar.py
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from __future__ import print_function
import sys
import torch
import torch.nn as nn
import torch.optim as optim
import torch.nn.functional as F
import torch.backends.cudnn as cudnn
import random
import os
import argparse
import numpy as np
from PreResNet import *
from sklearn.mixture import GaussianMixture
import dataloader_cifar as dataloader
parser = argparse.ArgumentParser(description='PyTorch CIFAR Training')
parser.add_argument('--batch_size', default=64, type=int, help='train batchsize')
parser.add_argument('--lr', '--learning_rate', default=0.02, type=float, help='initial learning rate')
parser.add_argument('--noise_mode', default='sym')
parser.add_argument('--alpha', default=4, type=float, help='parameter for Beta')
parser.add_argument('--lambda_u', default=25, type=float, help='weight for unsupervised loss')
parser.add_argument('--p_threshold', default=0.5, type=float, help='clean probability threshold')
parser.add_argument('--T', default=0.5, type=float, help='sharpening temperature')
parser.add_argument('--num_epochs', default=300, type=int)
parser.add_argument('--r', default=0.5, type=float, help='noise ratio')
parser.add_argument('--id', default='')
parser.add_argument('--seed', default=123)
parser.add_argument('--gpuid', default=0, type=int)
parser.add_argument('--num_class', default=10, type=int)
parser.add_argument('--data_path', default='./cifar-10', type=str, help='path to dataset')
parser.add_argument('--dataset', default='cifar10', type=str)
args = parser.parse_args()
torch.cuda.set_device(args.gpuid)
random.seed(args.seed)
torch.manual_seed(args.seed)
torch.cuda.manual_seed_all(args.seed)
# Training
def train(epoch,net,net2,optimizer,labeled_trainloader,unlabeled_trainloader):
net.train()
net2.eval() #fix one network and train the other
unlabeled_train_iter = iter(unlabeled_trainloader)
num_iter = (len(labeled_trainloader.dataset)//args.batch_size)+1
for batch_idx, (inputs_x, inputs_x2, labels_x, w_x) in enumerate(labeled_trainloader):
try:
inputs_u, inputs_u2 = unlabeled_train_iter.next()
except:
unlabeled_train_iter = iter(unlabeled_trainloader)
inputs_u, inputs_u2 = unlabeled_train_iter.next()
batch_size = inputs_x.size(0)
# Transform label to one-hot
labels_x = torch.zeros(batch_size, args.num_class).scatter_(1, labels_x.view(-1,1), 1)
w_x = w_x.view(-1,1).type(torch.FloatTensor)
inputs_x, inputs_x2, labels_x, w_x = inputs_x.cuda(), inputs_x2.cuda(), labels_x.cuda(), w_x.cuda()
inputs_u, inputs_u2 = inputs_u.cuda(), inputs_u2.cuda()
with torch.no_grad():
# label co-guessing of unlabeled samples
outputs_u11 = net(inputs_u)
outputs_u12 = net(inputs_u2)
outputs_u21 = net2(inputs_u)
outputs_u22 = net2(inputs_u2)
pu = (torch.softmax(outputs_u11, dim=1) + torch.softmax(outputs_u12, dim=1) + torch.softmax(outputs_u21, dim=1) + torch.softmax(outputs_u22, dim=1)) / 4
ptu = pu**(1/args.T) # temparature sharpening
targets_u = ptu / ptu.sum(dim=1, keepdim=True) # normalize
targets_u = targets_u.detach()
# label refinement of labeled samples
outputs_x = net(inputs_x)
outputs_x2 = net(inputs_x2)
px = (torch.softmax(outputs_x, dim=1) + torch.softmax(outputs_x2, dim=1)) / 2
px = w_x*labels_x + (1-w_x)*px
ptx = px**(1/args.T) # temparature sharpening
targets_x = ptx / ptx.sum(dim=1, keepdim=True) # normalize
targets_x = targets_x.detach()
# mixmatch
l = np.random.beta(args.alpha, args.alpha)
l = max(l, 1-l)
all_inputs = torch.cat([inputs_x, inputs_x2, inputs_u, inputs_u2], dim=0)
all_targets = torch.cat([targets_x, targets_x, targets_u, targets_u], dim=0)
idx = torch.randperm(all_inputs.size(0))
input_a, input_b = all_inputs, all_inputs[idx]
target_a, target_b = all_targets, all_targets[idx]
mixed_input = l * input_a + (1 - l) * input_b
mixed_target = l * target_a + (1 - l) * target_b
logits = net(mixed_input)
logits_x = logits[:batch_size*2]
logits_u = logits[batch_size*2:]
Lx, Lu, lamb = criterion(logits_x, mixed_target[:batch_size*2], logits_u, mixed_target[batch_size*2:], epoch+batch_idx/num_iter, warm_up)
# regularization
prior = torch.ones(args.num_class)/args.num_class
prior = prior.cuda()
pred_mean = torch.softmax(logits, dim=1).mean(0)
penalty = torch.sum(prior*torch.log(prior/pred_mean))
loss = Lx + lamb * Lu + penalty
# compute gradient and do SGD step
optimizer.zero_grad()
loss.backward()
optimizer.step()
sys.stdout.write('\r')
sys.stdout.write('%s:%.1f-%s | Epoch [%3d/%3d] Iter[%3d/%3d]\t Labeled loss: %.2f Unlabeled loss: %.2f'
%(args.dataset, args.r, args.noise_mode, epoch, args.num_epochs, batch_idx+1, num_iter, Lx.item(), Lu.item()))
sys.stdout.flush()
def warmup(epoch,net,optimizer,dataloader):
net.train()
num_iter = (len(dataloader.dataset)//dataloader.batch_size)+1
for batch_idx, (inputs, labels, path) in enumerate(dataloader):
inputs, labels = inputs.cuda(), labels.cuda()
optimizer.zero_grad()
outputs = net(inputs)
loss = CEloss(outputs, labels)
if args.noise_mode=='asym': # penalize confident prediction for asymmetric noise
penalty = conf_penalty(outputs)
L = loss + penalty
elif args.noise_mode=='sym':
L = loss
L.backward()
optimizer.step()
sys.stdout.write('\r')
sys.stdout.write('%s:%.1f-%s | Epoch [%3d/%3d] Iter[%3d/%3d]\t CE-loss: %.4f'
%(args.dataset, args.r, args.noise_mode, epoch, args.num_epochs, batch_idx+1, num_iter, loss.item()))
sys.stdout.flush()
def test(epoch,net1,net2):
net1.eval()
net2.eval()
correct = 0
total = 0
with torch.no_grad():
for batch_idx, (inputs, targets) in enumerate(test_loader):
inputs, targets = inputs.cuda(), targets.cuda()
outputs1 = net1(inputs)
outputs2 = net2(inputs)
outputs = outputs1+outputs2
_, predicted = torch.max(outputs, 1)
total += targets.size(0)
correct += predicted.eq(targets).cpu().sum().item()
acc = 100.*correct/total
print("\n| Test Epoch #%d\t Accuracy: %.2f%%\n" %(epoch,acc))
test_log.write('Epoch:%d Accuracy:%.2f\n'%(epoch,acc))
test_log.flush()
def eval_train(model,all_loss):
model.eval()
losses = torch.zeros(50000)
with torch.no_grad():
for batch_idx, (inputs, targets, index) in enumerate(eval_loader):
inputs, targets = inputs.cuda(), targets.cuda()
outputs = model(inputs)
loss = CE(outputs, targets)
for b in range(inputs.size(0)):
losses[index[b]]=loss[b]
losses = (losses-losses.min())/(losses.max()-losses.min())
all_loss.append(losses)
if args.r==0.9: # average loss over last 5 epochs to improve convergence stability
history = torch.stack(all_loss)
input_loss = history[-5:].mean(0)
input_loss = input_loss.reshape(-1,1)
else:
input_loss = losses.reshape(-1,1)
# fit a two-component GMM to the loss
gmm = GaussianMixture(n_components=2,max_iter=10,tol=1e-2,reg_covar=5e-4)
gmm.fit(input_loss)
prob = gmm.predict_proba(input_loss)
prob = prob[:,gmm.means_.argmin()]
return prob,all_loss
def linear_rampup(current, warm_up, rampup_length=16):
current = np.clip((current-warm_up) / rampup_length, 0.0, 1.0)
return args.lambda_u*float(current)
class SemiLoss(object):
def __call__(self, outputs_x, targets_x, outputs_u, targets_u, epoch, warm_up):
probs_u = torch.softmax(outputs_u, dim=1)
Lx = -torch.mean(torch.sum(F.log_softmax(outputs_x, dim=1) * targets_x, dim=1))
Lu = torch.mean((probs_u - targets_u)**2)
return Lx, Lu, linear_rampup(epoch,warm_up)
class NegEntropy(object):
def __call__(self,outputs):
probs = torch.softmax(outputs, dim=1)
return torch.mean(torch.sum(probs.log()*probs, dim=1))
def create_model():
model = ResNet18(num_classes=args.num_class)
model = model.cuda()
return model
stats_log=open('./checkpoint/%s_%.1f_%s'%(args.dataset,args.r,args.noise_mode)+'_stats.txt','w')
test_log=open('./checkpoint/%s_%.1f_%s'%(args.dataset,args.r,args.noise_mode)+'_acc.txt','w')
if args.dataset=='cifar10':
warm_up = 10
elif args.dataset=='cifar100':
warm_up = 30
loader = dataloader.cifar_dataloader(args.dataset,r=args.r,noise_mode=args.noise_mode,batch_size=args.batch_size,num_workers=5,\
root_dir=args.data_path,log=stats_log,noise_file='%s/%.1f_%s.json'%(args.data_path,args.r,args.noise_mode))
print('| Building net')
net1 = create_model()
net2 = create_model()
cudnn.benchmark = True
criterion = SemiLoss()
optimizer1 = optim.SGD(net1.parameters(), lr=args.lr, momentum=0.9, weight_decay=5e-4)
optimizer2 = optim.SGD(net2.parameters(), lr=args.lr, momentum=0.9, weight_decay=5e-4)
CE = nn.CrossEntropyLoss(reduction='none')
CEloss = nn.CrossEntropyLoss()
if args.noise_mode=='asym':
conf_penalty = NegEntropy()
all_loss = [[],[]] # save the history of losses from two networks
for epoch in range(args.num_epochs+1):
lr=args.lr
if epoch >= 150:
lr /= 10
for param_group in optimizer1.param_groups:
param_group['lr'] = lr
for param_group in optimizer2.param_groups:
param_group['lr'] = lr
test_loader = loader.run('test')
eval_loader = loader.run('eval_train')
if epoch<warm_up:
warmup_trainloader = loader.run('warmup')
print('Warmup Net1')
warmup(epoch,net1,optimizer1,warmup_trainloader)
print('\nWarmup Net2')
warmup(epoch,net2,optimizer2,warmup_trainloader)
else:
prob1,all_loss[0]=eval_train(net1,all_loss[0])
prob2,all_loss[1]=eval_train(net2,all_loss[1])
pred1 = (prob1 > args.p_threshold)
pred2 = (prob2 > args.p_threshold)
print('Train Net1')
labeled_trainloader, unlabeled_trainloader = loader.run('train',pred2,prob2) # co-divide
train(epoch,net1,net2,optimizer1,labeled_trainloader, unlabeled_trainloader) # train net1
print('\nTrain Net2')
labeled_trainloader, unlabeled_trainloader = loader.run('train',pred1,prob1) # co-divide
train(epoch,net2,net1,optimizer2,labeled_trainloader, unlabeled_trainloader) # train net2
test(epoch,net1,net2)