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import torch
import torch.nn as nn
import torch.nn.functional as F
import numpy as np
from methods.tool_func import *
def preprocessing(x_fea):
# x_fea: [B, 197, 384] --> x_cls_fea [B, 1, 384], x_patch_fea [B, 384, 14, 14]
B, num, dim = x_fea.size()[0], x_fea.size()[1], x_fea.size()[2]
x_cls_fea = x_fea[:, :1, :]
x_patch_fea = x_fea[:,1:, :]
x_patch_fea = x_patch_fea.contiguous().view(B,dim,num-1).view(B, dim, 14, 14)
return x_cls_fea, x_patch_fea
def postprocessing(x_cls_fea, x_patch_fea):
# x_cls_fea [B, 1, 384], x_patch_fea [B, 384, 14, 14] --> x_fea: [B, 197, 384]
B, num, dim = x_patch_fea.size()[0], x_patch_fea.size()[2]*x_patch_fea.size()[3]+1, x_patch_fea.size()[1]
x_patch_fea = x_patch_fea.contiguous().view(B,dim,num-1).view(B,num-1,dim)
x_fea = torch.cat((x_cls_fea, x_patch_fea), 1)
return x_fea
def changeNewAdvStyle_ViT(vit_fea, new_styleAug_mean, new_styleAug_std, p_thred):
if(new_styleAug_mean=='None'):
return vit_fea
#final
p = np.random.uniform()
if( p < p_thred):
return vit_fea
cls_fea, input_fea = preprocessing(vit_fea)
feat_size = input_fea.size()
ori_style_mean, ori_style_std = calc_mean_std(input_fea)
#print('ori mean:', ori_style_mean.mean(), 'ori std:', ori_style_std.mean())
#print('adv mean:', new_styleAug_mean.mean(), 'adv std:', new_styleAug_std.mean())
#print('mean diff:', new_styleAug_mean.mean() - ori_style_mean.mean(), 'std diff:', new_styleAug_std.mean() - ori_style_std.mean())
normalized_fea = (input_fea - ori_style_mean.expand(feat_size)) / ori_style_std.expand(feat_size)
styleAug_fea = normalized_fea * new_styleAug_std.expand(feat_size) + new_styleAug_mean.expand(feat_size)
styleAug_fea_vit = postprocessing(cls_fea, styleAug_fea)
return styleAug_fea_vit
class ProtoNet(nn.Module):
def __init__(self, backbone):
super().__init__()
# bias & scale of cosine classifier
self.bias = nn.Parameter(torch.FloatTensor(1).fill_(0), requires_grad=True)
self.scale_cls = nn.Parameter(torch.FloatTensor(1).fill_(10), requires_grad=True)
# backbone
self.feature = backbone
final_feat_dim = 384
self.classifier = nn.Linear(final_feat_dim, 64)
self.loss_fn = nn.CrossEntropyLoss()
def cos_classifier(self, w, f):
"""
w.shape = B, nC, d
f.shape = B, M, d
"""
f = F.normalize(f, p=2, dim=f.dim()-1, eps=1e-12)
w = F.normalize(w, p=2, dim=w.dim()-1, eps=1e-12)
cls_scores = f @ w.transpose(1, 2) # B, M, nC
cls_scores = self.scale_cls * (cls_scores + self.bias)
return cls_scores
def forward(self, supp_x, supp_y, x):
"""
supp_x.shape = [B, nSupp, C, H, W]
supp_y.shape = [B, nSupp]
x.shape = [B, nQry, C, H, W]
"""
num_classes = supp_y.max() + 1 # NOTE: assume B==1
B, nSupp, C, H, W = supp_x.shape
supp_f = self.feature.forward(supp_x.contiguous().view(-1, C, H, W))
supp_f = supp_f.view(B, nSupp, -1)
supp_y_1hot = F.one_hot(supp_y, num_classes).transpose(1, 2) # B, nC, nSupp
# B, nC, nSupp x B, nSupp, d = B, nC, d
prototypes = torch.bmm(supp_y_1hot.float(), supp_f)
prototypes = prototypes / supp_y_1hot.sum(dim=2, keepdim=True) # NOTE: may div 0 if some classes got 0 images
feat = self.feature.forward(x.view(-1, C, H, W))
feat = feat.view(B, x.shape[1], -1) # B, nQry, d
logits = self.cos_classifier(prototypes, feat) # B, nQry, nC
return logits
def set_statues_of_modules(self, flag):
if(flag=='eval'):
self.feature.eval()
self.classifier.eval()
#self.scale_cls.eval()
#self.bias.eval()
elif(flag=='train'):
self.feature.train()
self.classifier.train()
#self.scale_cls.train()
#self.bias.train()
return
def forward_protonet(self, episode_f,supp_y, B, nSupp, nQuery, num_classes):
#print('episode_f:', episode_f.size())
episode_f = episode_f.view(num_classes, nSupp + nQuery, -1)
#print('episode_f:', episode_f.size())
fea_dim = episode_f.size()[-1]
supp_f = episode_f[:, :nSupp, :].contiguous().view(-1, fea_dim).unsqueeze(0)
query_f = episode_f[:, nSupp:, :].contiguous().view(-1, fea_dim).unsqueeze(0)
supp_y_1hot = F.one_hot(supp_y, num_classes).transpose(1, 2) # B, nC, nSupp
# B, nC, nSupp x B, nSupp, d = B, nC, d
prototypes = torch.bmm(supp_y_1hot.float(), supp_f)
prototypes = prototypes / supp_y_1hot.sum(dim=2, keepdim=True) # NOTE: may div 0 if some classes got 0 images
logits = self.cos_classifier(prototypes, query_f) # B, nQry, nC
return logits
def adversarial_attack_Incre(self, x_ori, y_ori, epsilon_list):
x_ori = x_ori.cuda()
y_ori = y_ori.cuda()
x_size = x_ori.size()
x_ori = x_ori.view(x_size[0]*x_size[1], x_size[2], x_size[3], x_size[4])
y_ori = y_ori.view(x_size[0]*x_size[1])
# if not adv, set defalut = 'None'
adv_style_mean_block1, adv_style_std_block1 = 'None', 'None'
adv_style_mean_block2, adv_style_std_block2 = 'None', 'None'
adv_style_mean_block3, adv_style_std_block3 = 'None', 'None'
# forward and set the grad = True
blocklist = 'block123'
if('1' in blocklist and epsilon_list[0] != 0 ):
x_ori_block1 = self.feature.forward_block1(x_ori)
x_ori_block1_cls, x_ori_block1_P = preprocessing(x_ori_block1)
feat_size_block1 = x_ori_block1_P.size()
#print('x_ori_block1:', x_ori_block1.size(), x_ori_block1_P.size())
ori_style_mean_block1, ori_style_std_block1 = calc_mean_std(x_ori_block1_P)
# set them as learnable parameters
ori_style_mean_block1 = torch.nn.Parameter(ori_style_mean_block1)
ori_style_std_block1 = torch.nn.Parameter(ori_style_std_block1)
ori_style_mean_block1.requires_grad_()
ori_style_std_block1.requires_grad_()
# contain ori_style_mean_block1 in the graph
x_normalized_block1 = (x_ori_block1_P - ori_style_mean_block1.detach().expand(feat_size_block1)) / ori_style_std_block1.detach().expand(feat_size_block1)
x_ori_block1_P = x_normalized_block1 * ori_style_std_block1.expand(feat_size_block1) + ori_style_mean_block1.expand(feat_size_block1)
x_ori_block1 = postprocessing(x_ori_block1_cls, x_ori_block1_P)
#print('x_ori_block1:', x_ori_block1.size())
# pass the rest model
x_ori_block2 = self.feature.forward_block2(x_ori_block1)
x_ori_block3 = self.feature.forward_block3(x_ori_block2)
x_ori_block4 = self.feature.forward_block4(x_ori_block3)
x_ori_fea = self.feature.forward_rest(x_ori_block4)
x_ori_output = self.classifier.forward(x_ori_fea)
# calculate initial pred, loss and acc
ori_pred = x_ori_output.max(1, keepdim=True)[1]
ori_loss = self.loss_fn(x_ori_output, y_ori)
ori_acc = (ori_pred == y_ori).type(torch.float).sum().item() / y_ori.size()[0]
# zero all the existing gradients
self.feature.zero_grad()
self.classifier.zero_grad()
# backward loss
ori_loss.backward()
# collect datagrad
grad_ori_style_mean_block1 = ori_style_mean_block1.grad.detach()
grad_ori_style_std_block1 = ori_style_std_block1.grad.detach()
# fgsm style attack
index = torch.randint(0, len(epsilon_list), (1, ))[0]
epsilon = epsilon_list[index]
adv_style_mean_block1 = fgsm_attack(ori_style_mean_block1, epsilon, grad_ori_style_mean_block1)
adv_style_std_block1 = fgsm_attack(ori_style_std_block1, epsilon, grad_ori_style_std_block1)
# add zero_grad
self.feature.zero_grad()
self.classifier.zero_grad()
if('2' in blocklist and epsilon_list[1] != 0):
x_ori_block1 = self.feature.forward_block1(x_ori)
# update adv_block1
x_adv_block1 = changeNewAdvStyle_ViT(x_ori_block1, adv_style_mean_block1, adv_style_std_block1, p_thred=0)
# forward block2
x_ori_block2 = self.feature.forward_block2(x_adv_block1)
# calculate mean and std
x_ori_block2_cls , x_ori_block2_P = preprocessing(x_ori_block2)
feat_size_block2 = x_ori_block2_P.size()
ori_style_mean_block2, ori_style_std_block2 = calc_mean_std(x_ori_block2_P)
# set them as learnable parameters
ori_style_mean_block2 = torch.nn.Parameter(ori_style_mean_block2)
ori_style_std_block2 = torch.nn.Parameter(ori_style_std_block2)
ori_style_mean_block2.requires_grad_()
ori_style_std_block2.requires_grad_()
# contain ori_style_mean_block1 in the graph
x_normalized_block2 = (x_ori_block2_P - ori_style_mean_block2.detach().expand(feat_size_block2)) / ori_style_std_block2.detach().expand(feat_size_block2)
x_ori_block2_P = x_normalized_block2 * ori_style_std_block2.expand(feat_size_block2) + ori_style_mean_block2.expand(feat_size_block2)
x_ori_block2 = postprocessing(x_ori_block2_cls, x_ori_block2_P)
# pass the rest model
x_ori_block3 = self.feature.forward_block3(x_ori_block2)
x_ori_block4 = self.feature.forward_block4(x_ori_block3)
x_ori_fea = self.feature.forward_rest(x_ori_block4)
x_ori_output = self.classifier.forward(x_ori_fea)
# calculate initial pred, loss and acc
ori_pred = x_ori_output.max(1, keepdim=True)[1]
ori_loss = self.loss_fn(x_ori_output, y_ori)
ori_acc = (ori_pred == y_ori).type(torch.float).sum().item() / y_ori.size()[0]
#print('ori_pred:', ori_pred, 'ori_loss:', ori_loss, 'ori_acc:', ori_acc)
# zero all the existing gradients
self.feature.zero_grad()
self.classifier.zero_grad()
# backward loss
ori_loss.backward()
# collect datagrad
grad_ori_style_mean_block2 = ori_style_mean_block2.grad.detach()
grad_ori_style_std_block2 = ori_style_std_block2.grad.detach()
# fgsm style attack
index = torch.randint(0, len(epsilon_list), (1, ))[0]
epsilon = epsilon_list[index]
adv_style_mean_block2 = fgsm_attack(ori_style_mean_block2, epsilon, grad_ori_style_mean_block2)
adv_style_std_block2 = fgsm_attack(ori_style_std_block2, epsilon, grad_ori_style_std_block2)
#print('adv_style_mean_block2:', adv_style_mean_block2.size(), 'adv_style_std_block2:', adv_style_std_block2.size())
# add zero_grad
self.feature.zero_grad()
self.classifier.zero_grad()
if('3' in blocklist and epsilon_list[2] != 0):
x_ori_block1 = self.feature.forward_block1(x_ori)
x_adv_block1 = changeNewAdvStyle_ViT(x_ori_block1, adv_style_mean_block1, adv_style_std_block1, p_thred=0)
x_ori_block2 = self.feature.forward_block2(x_adv_block1)
x_adv_block2 = changeNewAdvStyle_ViT(x_ori_block2, adv_style_mean_block2, adv_style_std_block2, p_thred=0)
x_ori_block3 = self.feature.forward_block3(x_adv_block2)
x_ori_block3_cls, x_ori_block3_P = preprocessing(x_ori_block3)
# calculate mean and std
feat_size_block3 = x_ori_block3_P.size()
ori_style_mean_block3, ori_style_std_block3 = calc_mean_std(x_ori_block3_P)
# set them as learnable parameters
ori_style_mean_block3 = torch.nn.Parameter(ori_style_mean_block3)
ori_style_std_block3 = torch.nn.Parameter(ori_style_std_block3)
ori_style_mean_block3.requires_grad_()
ori_style_std_block3.requires_grad_()
# contain ori_style_mean_block3 in the graph
x_normalized_block3 = (x_ori_block3_P - ori_style_mean_block3.detach().expand(feat_size_block3)) / ori_style_std_block3.detach().expand(feat_size_block3)
x_ori_block3_P = x_normalized_block3 * ori_style_std_block3.expand(feat_size_block3) + ori_style_mean_block3.expand(feat_size_block3)
x_ori_block3 = postprocessing(x_ori_block3_cls, x_ori_block3_P)
# pass the rest model
x_ori_block4 = self.feature.forward_block4(x_ori_block3)
x_ori_fea = self.feature.forward_rest(x_ori_block4)
x_ori_output = self.classifier.forward(x_ori_fea)
# calculate initial pred, loss and acc
ori_pred = x_ori_output.max(1, keepdim=True)[1]
ori_loss = self.loss_fn(x_ori_output, y_ori)
ori_acc = (ori_pred == y_ori).type(torch.float).sum().item() / y_ori.size()[0]
# zero all the existing gradients
self.feature.zero_grad()
self.classifier.zero_grad()
# backward loss
ori_loss.backward()
# collect datagrad
grad_ori_style_mean_block3 = ori_style_mean_block3.grad.detach()
grad_ori_style_std_block3 = ori_style_std_block3.grad.detach()
# fgsm style attack
index = torch.randint(0, len(epsilon_list), (1, ))[0]
epsilon = epsilon_list[index]
adv_style_mean_block3 = fgsm_attack(ori_style_mean_block3, epsilon, grad_ori_style_mean_block3)
adv_style_std_block3 = fgsm_attack(ori_style_std_block3, epsilon, grad_ori_style_std_block3)
return adv_style_mean_block1, adv_style_std_block1, adv_style_mean_block2, adv_style_std_block2, adv_style_mean_block3, adv_style_std_block3
def set_forward_loss_StyAdv(self, SupportTensor,QueryTensor,SupportLabel, QueryLabel, GlobalID_S,GlobalID_Q, epsilon_list):
##################################################################
'''
supp_x.shape = [B, nSupp, C, H, W]
supp_y.shape = [B, nSupp]
x.shape = [B, nQry, C, H, W]
# to tacke the input data
x_ori: [5, 21, 3, 224, 224], global_y: [5, 21]
'''
# to resize as x_ori: torch.Size([5, 21, 3, 224, 224]) global_y: torch.Size([5, 21])
B = SupportTensor.size()[0]
num_classes = SupportLabel.max() + 1 # NOTE: assume B==1
SupportTensor = SupportTensor.squeeze().view(num_classes, -1, 3, 224, 224)
QueryTensor = QueryTensor.squeeze().view(num_classes, -1, 3, 224, 224)
nSupp = SupportTensor.size()[1]
nQuery = QueryTensor.size()[1]
x_ori = torch.cat((SupportTensor, QueryTensor), dim=1)
global_y = torch.cat((GlobalID_S.view(num_classes, nSupp), GlobalID_Q.view(num_classes, nQuery)), dim=1)
#print('x_ori:', x_ori.size(), 'global_y:', global_y.size())
##################################################################
# 0. first cp x_adv from x_ori
x_adv = x_ori
# 1. styleAdv
self.set_statues_of_modules('eval')
adv_style_mean_block1, adv_style_std_block1, adv_style_mean_block2, adv_style_std_block2, adv_style_mean_block3, adv_style_std_block3 = self.adversarial_attack_Incre(x_ori, global_y, epsilon_list)
self.feature.zero_grad()
self.classifier.zero_grad()
# 2. forward and get loss
self.set_statues_of_modules('train')
x_ori = x_ori.cuda()
x_size = x_ori.size()
x_ori = x_ori.view(num_classes*(nSupp+nQuery), 3, 224, 224)
global_y = global_y.view(num_classes*(nSupp+nQuery)).cuda()
x_ori_block1 = self.feature.forward_block1(x_ori)
x_ori_block2 = self.feature.forward_block2(x_ori_block1)
x_ori_block3 = self.feature.forward_block3(x_ori_block2)
x_ori_block4 = self.feature.forward_block4(x_ori_block3)
x_ori_fea = self.feature.forward_rest(x_ori_block4)
# 3. ori cls global loss
scores_cls_ori = self.classifier.forward(x_ori_fea)
loss_cls_ori = self.loss_fn(scores_cls_ori, global_y)
# 4. ori FSL scores and losses
scores_fsl_ori = self.forward_protonet(x_ori_fea, SupportLabel,B, nSupp, nQuery, num_classes)
scores_fsl_ori = scores_fsl_ori.view(num_classes*nQuery, -1)
QueryLabel = QueryLabel.view(-1)
loss_fsl_ori = self.loss_fn(scores_fsl_ori, QueryLabel)
# 5. forward StyleAdv
x_adv = x_adv.cuda()
x_adv = x_adv.view(x_size[0]*x_size[1], x_size[2], x_size[3], x_size[4])
x_adv_block1 = self.feature.forward_block1(x_adv)
x_adv_block1_newStyle = changeNewAdvStyle_ViT(x_adv_block1, adv_style_mean_block1, adv_style_std_block1, p_thred = P_THRED)
x_adv_block2 = self.feature.forward_block2(x_adv_block1_newStyle)
x_adv_block2_newStyle = changeNewAdvStyle_ViT(x_adv_block2, adv_style_mean_block2, adv_style_std_block2, p_thred = P_THRED)
x_adv_block3 = self.feature.forward_block3(x_adv_block2_newStyle)
x_adv_block3_newStyle = changeNewAdvStyle_ViT(x_adv_block3, adv_style_mean_block3, adv_style_std_block3, p_thred = P_THRED)
x_adv_block4 = self.feature.forward_block4(x_adv_block3_newStyle)
x_adv_fea = self.feature.forward_rest(x_adv_block4)
# 6. adv cls gloabl loss
scores_cls_adv = self.classifier.forward(x_adv_fea)
loss_cls_adv = self.loss_fn(scores_cls_adv, global_y)
# 7. adv FSL scores and losses
scores_fsl_adv = self.forward_protonet(x_adv_fea, SupportLabel,B, nSupp, nQuery, num_classes)
scores_fsl_adv = scores_fsl_adv.view(num_classes*nQuery, -1)
loss_fsl_adv = self.loss_fn(scores_fsl_adv, QueryLabel)
return scores_fsl_ori, loss_fsl_ori, scores_cls_ori, loss_cls_ori, scores_fsl_adv, loss_fsl_adv, scores_cls_adv, loss_cls_adv
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