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DIS-SAM / IS_Net /models /isnet.py
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 import torch
import torch.nn as nn
from torchvision import models
import torch.nn.functional as F
from timm.models.layers import trunc_normal_, DropPath
import matplotlib.pyplot as plt
import monai
def iou_loss(pred, mask):
inter = (pred * mask).sum(dim=(2, 3)) #交集
union = (pred + mask).sum(dim=(2, 3)) - inter #并集-交集
iou = 1 - (inter + 1) / (union + 1)
return iou.mean()
bce_loss = nn.BCELoss(reduction='mean')
def muti_loss_fusion(preds, target):
loss0 = 0.0
loss = 0.0
for i in range(0,len(preds)):
# print("i: ", i, preds[i].shape)
if(preds[i].shape[2]!=target.shape[2] or preds[i].shape[3]!=target.shape[3]):
# tmp_target = _upsample_like(target,preds[i])
tmp_target = F.interpolate(target, size=preds[i].size()[2:], mode='bilinear', align_corners=True)
loss = loss + 20*bce_loss(preds[i],tmp_target) + 0.5*iou_loss(preds[i],tmp_target)
# loss = loss + bce_loss(preds[i],tmp_target)+ iou_loss(preds[i],tmp_target)
# loss = loss + bce_loss(preds[i],tmp_target)
else:
loss = loss + 20*bce_loss(preds[i],target) + 0.5*iou_loss(preds[i],target)
# loss = loss + bce_loss(preds[i],target) + iou_loss(preds[i],target)
# loss = loss + bce_loss(preds[i],target)
if(i==0):
loss0 = loss
return loss0, loss
MSE_loss = nn.MSELoss(reduction='mean')
kl_loss = nn.KLDivLoss(reduction='mean')
l1_loss = nn.L1Loss(reduction='mean')
smooth_l1_loss = nn.SmoothL1Loss(reduction='mean')
def muti_loss_fusion_kl(preds, target, dfs, fs, mode='MSE'):
loss0 = 0.0
loss = 0.0
for i in range(0,len(preds)):
# print("i: ", i, preds[i].shape)
if(preds[i].shape[2]!=target.shape[2] or preds[i].shape[3]!=target.shape[3]):
# tmp_target = _upsample_like(target,preds[i])
tmp_target = F.interpolate(target, size=preds[i].size()[2:], mode='bilinear', align_corners=True)
loss = loss + 20*bce_loss(preds[i],tmp_target) + 0.5*iou_loss(preds[i],tmp_target)
# loss = loss + bce_loss(preds[i],tmp_target) + iou_loss(preds[i],tmp_target)
# loss = loss + bce_loss(preds[i],tmp_target)
else:
loss = loss + 20*bce_loss(preds[i],target) + 0.5*iou_loss(preds[i],target)
# loss = loss + bce_loss(preds[i],target) + iou_loss(preds[i],target)
# loss = loss + bce_loss(preds[i],target)
if(i==0):
loss0 = loss
for i in range(0,len(dfs)):
if(mode=='MSE'):
loss = loss + MSE_loss(dfs[i],fs[i]) ### add the mse loss of features as additional constraints
# print("fea_loss: ", fea_loss(dfs[i],fs[i]).item())
elif(mode=='KL'):
loss = loss + kl_loss(F.log_softmax(dfs[i],dim=1),F.softmax(fs[i],dim=1))
# print("kl_loss: ", kl_loss(F.log_softmax(dfs[i],dim=1),F.softmax(fs[i],dim=1)).item())
elif(mode=='MAE'):
loss = loss + l1_loss(dfs[i],fs[i])
# print("ls_loss: ", l1_loss(dfs[i],fs[i]))
elif(mode=='SmoothL1'):
loss = loss + smooth_l1_loss(dfs[i],fs[i])
# print("SmoothL1: ", smooth_l1_loss(dfs[i],fs[i]).item())
return loss0, loss
class REBNCONV(nn.Module):
def __init__(self,in_ch=3,out_ch=3,dirate=1,stride=1):
super(REBNCONV,self).__init__()
self.conv_s1 = nn.Conv2d(in_ch,out_ch,3,padding=1*dirate,dilation=1*dirate,stride=stride)
self.bn_s1 = nn.BatchNorm2d(out_ch)
self.relu_s1 = nn.ReLU(inplace=True)
def forward(self,x):
hx = x
xout = self.relu_s1(self.bn_s1(self.conv_s1(hx)))
return xout
## upsample tensor 'src' to have the same spatial size with tensor 'tar'
def _upsample_like(src,tar):
src = F.upsample(src,size=tar.shape[2:],mode='bilinear')
return src
### RSU-7 ###
class RSU7(nn.Module):
def __init__(self, in_ch=3, mid_ch=12, out_ch=3, img_size=512):
super(RSU7,self).__init__()
self.in_ch = in_ch
self.mid_ch = mid_ch
self.out_ch = out_ch
self.rebnconvin = REBNCONV(in_ch,out_ch,dirate=1) ## 1 -> 1/2
self.rebnconv1 = REBNCONV(out_ch,mid_ch,dirate=1)
self.pool1 = nn.MaxPool2d(2,stride=2,ceil_mode=True)
self.rebnconv2 = REBNCONV(mid_ch,mid_ch,dirate=1)
self.pool2 = nn.MaxPool2d(2,stride=2,ceil_mode=True)
self.rebnconv3 = REBNCONV(mid_ch,mid_ch,dirate=1)
self.pool3 = nn.MaxPool2d(2,stride=2,ceil_mode=True)
self.rebnconv4 = REBNCONV(mid_ch,mid_ch,dirate=1)
self.pool4 = nn.MaxPool2d(2,stride=2,ceil_mode=True)
self.rebnconv5 = REBNCONV(mid_ch,mid_ch,dirate=1)
self.pool5 = nn.MaxPool2d(2,stride=2,ceil_mode=True)
self.rebnconv6 = REBNCONV(mid_ch,mid_ch,dirate=1)
self.rebnconv7 = REBNCONV(mid_ch,mid_ch,dirate=2)
self.rebnconv6d = REBNCONV(mid_ch*2,mid_ch,dirate=1)
self.rebnconv5d = REBNCONV(mid_ch*2,mid_ch,dirate=1)
self.rebnconv4d = REBNCONV(mid_ch*2,mid_ch,dirate=1)
self.rebnconv3d = REBNCONV(mid_ch*2,mid_ch,dirate=1)
self.rebnconv2d = REBNCONV(mid_ch*2,mid_ch,dirate=1)
self.rebnconv1d = REBNCONV(mid_ch*2,out_ch,dirate=1)
def forward(self,x):
b, c, h, w = x.shape
hx = x
hxin = self.rebnconvin(hx)
hx1 = self.rebnconv1(hxin)
hx = self.pool1(hx1)
hx2 = self.rebnconv2(hx)
hx = self.pool2(hx2)
hx3 = self.rebnconv3(hx)
hx = self.pool3(hx3)
hx4 = self.rebnconv4(hx)
hx = self.pool4(hx4)
hx5 = self.rebnconv5(hx)
hx = self.pool5(hx5)
hx6 = self.rebnconv6(hx)
hx7 = self.rebnconv7(hx6)
hx6d = self.rebnconv6d(torch.cat((hx7,hx6),1))
hx6dup = _upsample_like(hx6d,hx5)
hx5d = self.rebnconv5d(torch.cat((hx6dup,hx5),1))
hx5dup = _upsample_like(hx5d,hx4)
hx4d = self.rebnconv4d(torch.cat((hx5dup,hx4),1))
hx4dup = _upsample_like(hx4d,hx3)
hx3d = self.rebnconv3d(torch.cat((hx4dup,hx3),1))
hx3dup = _upsample_like(hx3d,hx2)
hx2d = self.rebnconv2d(torch.cat((hx3dup,hx2),1))
hx2dup = _upsample_like(hx2d,hx1)
hx1d = self.rebnconv1d(torch.cat((hx2dup,hx1),1))
return hx1d + hxin
### RSU-6 ###
class RSU6(nn.Module):
def __init__(self, in_ch=3, mid_ch=12, out_ch=3):
super(RSU6,self).__init__()
self.rebnconvin = REBNCONV(in_ch,out_ch,dirate=1)
self.rebnconv1 = REBNCONV(out_ch,mid_ch,dirate=1)
self.pool1 = nn.MaxPool2d(2,stride=2,ceil_mode=True)
self.rebnconv2 = REBNCONV(mid_ch,mid_ch,dirate=1)
self.pool2 = nn.MaxPool2d(2,stride=2,ceil_mode=True)
self.rebnconv3 = REBNCONV(mid_ch,mid_ch,dirate=1)
self.pool3 = nn.MaxPool2d(2,stride=2,ceil_mode=True)
self.rebnconv4 = REBNCONV(mid_ch,mid_ch,dirate=1)
self.pool4 = nn.MaxPool2d(2,stride=2,ceil_mode=True)
self.rebnconv5 = REBNCONV(mid_ch,mid_ch,dirate=1)
self.rebnconv6 = REBNCONV(mid_ch,mid_ch,dirate=2)
self.rebnconv5d = REBNCONV(mid_ch*2,mid_ch,dirate=1)
self.rebnconv4d = REBNCONV(mid_ch*2,mid_ch,dirate=1)
self.rebnconv3d = REBNCONV(mid_ch*2,mid_ch,dirate=1)
self.rebnconv2d = REBNCONV(mid_ch*2,mid_ch,dirate=1)
self.rebnconv1d = REBNCONV(mid_ch*2,out_ch,dirate=1)
def forward(self,x):
hx = x
hxin = self.rebnconvin(hx)
hx1 = self.rebnconv1(hxin)
hx = self.pool1(hx1)
hx2 = self.rebnconv2(hx)
hx = self.pool2(hx2)
hx3 = self.rebnconv3(hx)
hx = self.pool3(hx3)
hx4 = self.rebnconv4(hx)
hx = self.pool4(hx4)
hx5 = self.rebnconv5(hx)
hx6 = self.rebnconv6(hx5)
hx5d = self.rebnconv5d(torch.cat((hx6,hx5),1))
hx5dup = _upsample_like(hx5d,hx4)
hx4d = self.rebnconv4d(torch.cat((hx5dup,hx4),1))
hx4dup = _upsample_like(hx4d,hx3)
hx3d = self.rebnconv3d(torch.cat((hx4dup,hx3),1))
hx3dup = _upsample_like(hx3d,hx2)
hx2d = self.rebnconv2d(torch.cat((hx3dup,hx2),1))
hx2dup = _upsample_like(hx2d,hx1)
hx1d = self.rebnconv1d(torch.cat((hx2dup,hx1),1))
return hx1d + hxin
### RSU-5 ###
class RSU5(nn.Module):
def __init__(self, in_ch=3, mid_ch=12, out_ch=3):
super(RSU5,self).__init__()
self.rebnconvin = REBNCONV(in_ch,out_ch,dirate=1)
self.rebnconv1 = REBNCONV(out_ch,mid_ch,dirate=1)
self.pool1 = nn.MaxPool2d(2,stride=2,ceil_mode=True)
self.rebnconv2 = REBNCONV(mid_ch,mid_ch,dirate=1)
self.pool2 = nn.MaxPool2d(2,stride=2,ceil_mode=True)
self.rebnconv3 = REBNCONV(mid_ch,mid_ch,dirate=1)
self.pool3 = nn.MaxPool2d(2,stride=2,ceil_mode=True)
self.rebnconv4 = REBNCONV(mid_ch,mid_ch,dirate=1)
self.rebnconv5 = REBNCONV(mid_ch,mid_ch,dirate=2)
self.rebnconv4d = REBNCONV(mid_ch*2,mid_ch,dirate=1)
self.rebnconv3d = REBNCONV(mid_ch*2,mid_ch,dirate=1)
self.rebnconv2d = REBNCONV(mid_ch*2,mid_ch,dirate=1)
self.rebnconv1d = REBNCONV(mid_ch*2,out_ch,dirate=1)
def forward(self,x):
hx = x
hxin = self.rebnconvin(hx)
hx1 = self.rebnconv1(hxin)
hx = self.pool1(hx1)
hx2 = self.rebnconv2(hx)
hx = self.pool2(hx2)
hx3 = self.rebnconv3(hx)
hx = self.pool3(hx3)
hx4 = self.rebnconv4(hx)
hx5 = self.rebnconv5(hx4)
hx4d = self.rebnconv4d(torch.cat((hx5,hx4),1))
hx4dup = _upsample_like(hx4d,hx3)
hx3d = self.rebnconv3d(torch.cat((hx4dup,hx3),1))
hx3dup = _upsample_like(hx3d,hx2)
hx2d = self.rebnconv2d(torch.cat((hx3dup,hx2),1))
hx2dup = _upsample_like(hx2d,hx1)
hx1d = self.rebnconv1d(torch.cat((hx2dup,hx1),1))
return hx1d + hxin
### RSU-4 ###
class RSU4(nn.Module):
def __init__(self, in_ch=3, mid_ch=12, out_ch=3):
super(RSU4,self).__init__()
self.rebnconvin = REBNCONV(in_ch,out_ch,dirate=1)
self.rebnconv1 = REBNCONV(out_ch,mid_ch,dirate=1)
self.pool1 = nn.MaxPool2d(2,stride=2,ceil_mode=True)
self.rebnconv2 = REBNCONV(mid_ch,mid_ch,dirate=1)
self.pool2 = nn.MaxPool2d(2,stride=2,ceil_mode=True)
self.rebnconv3 = REBNCONV(mid_ch,mid_ch,dirate=1)
self.rebnconv4 = REBNCONV(mid_ch,mid_ch,dirate=2)
self.rebnconv3d = REBNCONV(mid_ch*2,mid_ch,dirate=1)
self.rebnconv2d = REBNCONV(mid_ch*2,mid_ch,dirate=1)
self.rebnconv1d = REBNCONV(mid_ch*2,out_ch,dirate=1)
def forward(self,x):
hx = x
hxin = self.rebnconvin(hx)
hx1 = self.rebnconv1(hxin)
hx = self.pool1(hx1)
hx2 = self.rebnconv2(hx)
hx = self.pool2(hx2)
hx3 = self.rebnconv3(hx)
hx4 = self.rebnconv4(hx3)
hx3d = self.rebnconv3d(torch.cat((hx4,hx3),1))
hx3dup = _upsample_like(hx3d,hx2)
hx2d = self.rebnconv2d(torch.cat((hx3dup,hx2),1))
hx2dup = _upsample_like(hx2d,hx1)
hx1d = self.rebnconv1d(torch.cat((hx2dup,hx1),1))
return hx1d + hxin
### RSU-4F ###
class RSU4F(nn.Module):
def __init__(self, in_ch=3, mid_ch=12, out_ch=3):
super(RSU4F,self).__init__()
self.rebnconvin = REBNCONV(in_ch,out_ch,dirate=1)
self.rebnconv1 = REBNCONV(out_ch,mid_ch,dirate=1)
self.rebnconv2 = REBNCONV(mid_ch,mid_ch,dirate=2)
self.rebnconv3 = REBNCONV(mid_ch,mid_ch,dirate=4)
self.rebnconv4 = REBNCONV(mid_ch,mid_ch,dirate=8)
self.rebnconv3d = REBNCONV(mid_ch*2,mid_ch,dirate=4)
self.rebnconv2d = REBNCONV(mid_ch*2,mid_ch,dirate=2)
self.rebnconv1d = REBNCONV(mid_ch*2,out_ch,dirate=1)
def forward(self,x):
hx = x
hxin = self.rebnconvin(hx)
hx1 = self.rebnconv1(hxin)
hx2 = self.rebnconv2(hx1)
hx3 = self.rebnconv3(hx2)
hx4 = self.rebnconv4(hx3)
hx3d = self.rebnconv3d(torch.cat((hx4,hx3),1))
hx2d = self.rebnconv2d(torch.cat((hx3d,hx2),1))
hx1d = self.rebnconv1d(torch.cat((hx2d,hx1),1))
return hx1d + hxin
class myrebnconv(nn.Module):
def __init__(self, in_ch=3,
out_ch=1,
kernel_size=3,
stride=1,
padding=1,
dilation=1,
groups=1):
super(myrebnconv,self).__init__()
self.conv = nn.Conv2d(in_ch,
out_ch,
kernel_size=kernel_size,
stride=stride,
padding=padding,
dilation=dilation,
groups=groups)
self.bn = nn.BatchNorm2d(out_ch)
self.rl = nn.ReLU(inplace=True)
def forward(self,x):
return self.rl(self.bn(self.conv(x)))
class ISNetGTEncoder(nn.Module):
def __init__(self,in_ch=1,out_ch=1):
super(ISNetGTEncoder,self).__init__()
self.conv_in = myrebnconv(in_ch,16,3,stride=2,padding=1) # nn.Conv2d(in_ch,64,3,stride=2,padding=1)
self.stage1 = RSU7(16,16,64)
self.pool12 = nn.MaxPool2d(2,stride=2,ceil_mode=True)
self.stage2 = RSU6(64,16,64)
self.pool23 = nn.MaxPool2d(2,stride=2,ceil_mode=True)
self.stage3 = RSU5(64,32,128)
self.pool34 = nn.MaxPool2d(2,stride=2,ceil_mode=True)
self.stage4 = RSU4(128,32,256)
self.pool45 = nn.MaxPool2d(2,stride=2,ceil_mode=True)
self.stage5 = RSU4F(256,64,512)
self.pool56 = nn.MaxPool2d(2,stride=2,ceil_mode=True)
self.stage6 = RSU4F(512,64,512)
self.side1 = nn.Conv2d(64,out_ch,3,padding=1)
self.side2 = nn.Conv2d(64,out_ch,3,padding=1)
self.side3 = nn.Conv2d(128,out_ch,3,padding=1)
self.side4 = nn.Conv2d(256,out_ch,3,padding=1)
self.side5 = nn.Conv2d(512,out_ch,3,padding=1)
self.side6 = nn.Conv2d(512,out_ch,3,padding=1)
def compute_loss(self, preds, targets):
return muti_loss_fusion(preds,targets)
def forward(self,x):
hx = x
hxin = self.conv_in(hx)
# hx = self.pool_in(hxin)
#stage 1
hx1 = self.stage1(hxin)
hx = self.pool12(hx1)
#stage 2
hx2 = self.stage2(hx)
hx = self.pool23(hx2)
#stage 3
hx3 = self.stage3(hx)
hx = self.pool34(hx3)
#stage 4
hx4 = self.stage4(hx)
hx = self.pool45(hx4)
#stage 5
hx5 = self.stage5(hx)
hx = self.pool56(hx5)
#stage 6
hx6 = self.stage6(hx)
#side output
d1 = self.side1(hx1)
d1 = _upsample_like(d1,x)
d2 = self.side2(hx2)
d2 = _upsample_like(d2,x)
d3 = self.side3(hx3)
d3 = _upsample_like(d3,x)
d4 = self.side4(hx4)
d4 = _upsample_like(d4,x)
d5 = self.side5(hx5)
d5 = _upsample_like(d5,x)
d6 = self.side6(hx6)
d6 = _upsample_like(d6,x)
# d0 = self.outconv(torch.cat((d1,d2,d3,d4,d5,d6),1))
return [F.sigmoid(d1), F.sigmoid(d2), F.sigmoid(d3), F.sigmoid(d4), F.sigmoid(d5), F.sigmoid(d6)], [hx1,hx2,hx3,hx4,hx5,hx6]
class ISNetDIS(nn.Module):
def __init__(self,in_ch=3,out_ch=1):
super(ISNetDIS,self).__init__()
self.conv_in = nn.Conv2d(in_ch,64,3,stride=2,padding=1)
self.pool_in = nn.MaxPool2d(2,stride=2,ceil_mode=True)
self.stage1 = RSU7(64,32,64)
self.pool12 = nn.MaxPool2d(2,stride=2,ceil_mode=True)
self.stage2 = RSU6(64,32,128)
self.pool23 = nn.MaxPool2d(2,stride=2,ceil_mode=True)
self.stage3 = RSU5(128,64,256)
self.pool34 = nn.MaxPool2d(2,stride=2,ceil_mode=True)
self.stage4 = RSU4(256,128,512)
self.pool45 = nn.MaxPool2d(2,stride=2,ceil_mode=True)
self.stage5 = RSU4F(512,256,512)
self.pool56 = nn.MaxPool2d(2,stride=2,ceil_mode=True)
self.stage6 = RSU4F(512,256,512)
# decoder
self.stage5d = RSU4F(1024,256,512)
self.stage4d = RSU4(1024,128,256)
self.stage3d = RSU5(512,64,128)
self.stage2d = RSU6(256,32,64)
self.stage1d = RSU7(128,16,64)
self.side1 = nn.Conv2d(64,out_ch,3,padding=1)
self.side2 = nn.Conv2d(64,out_ch,3,padding=1)
self.side3 = nn.Conv2d(128,out_ch,3,padding=1)
self.side4 = nn.Conv2d(256,out_ch,3,padding=1)
self.side5 = nn.Conv2d(512,out_ch,3,padding=1)
self.side6 = nn.Conv2d(512,out_ch,3,padding=1)
# self.outconv = nn.Conv2d(6*out_ch,out_ch,1)
def compute_loss_kl(self, preds, targets, dfs, fs, mode='MSE'):
# return muti_loss_fusion(preds,targets)
return muti_loss_fusion_kl(preds, targets, dfs, fs, mode=mode)
def compute_loss(self, preds, targets):
# return muti_loss_fusion(preds,targets)
return muti_loss_fusion(preds, targets)
def forward(self,x):
hx = x
hxin = self.conv_in(hx)
#stage 1
hx1 = self.stage1(hxin)
hx = self.pool12(hx1)
#stage 2
hx2 = self.stage2(hx)
hx = self.pool23(hx2)
#stage 3
hx3 = self.stage3(hx)
hx = self.pool34(hx3)
#stage 4
hx4 = self.stage4(hx)
hx = self.pool45(hx4)
#stage 5
hx5 = self.stage5(hx)
hx = self.pool56(hx5)
#stage 6
hx6 = self.stage6(hx)
hx6up = _upsample_like(hx6,hx5)
#-------------------- decoder --------------------
hx5d = self.stage5d(torch.cat([hx6up,hx5],1))
hx5dup = _upsample_like(hx5d,hx4)
hx4d = self.stage4d(torch.cat([hx5dup,hx4],1))
hx4dup = _upsample_like(hx4d,hx3)
hx3d = self.stage3d(torch.cat([hx4dup,hx3],1))
hx3dup = _upsample_like(hx3d,hx2)
hx2d = self.stage2d(torch.cat([hx3dup,hx2],1))
hx2dup = _upsample_like(hx2d,hx1)
hx1d = self.stage1d(torch.cat([hx2dup,hx1],1))
#side output
d1 = self.side1(hx1d)
d1 = _upsample_like(d1,x)
d2 = self.side2(hx2d)
d2 = _upsample_like(d2,x)
d3 = self.side3(hx3d)
d3 = _upsample_like(d3,x)
d4 = self.side4(hx4d)
d4 = _upsample_like(d4,x)
d5 = self.side5(hx5d)
d5 = _upsample_like(d5,x)
d6 = self.side6(hx6)
d6 = _upsample_like(d6,x)
# d0 = self.outconv(torch.cat((d1,d2,d3,d4,d5,d6),1))
# plt.imshow(hx1d[0][0].cpu().detach().numpy(),cmap='gray')
# plt.show()
# plt.imshow(hx2d[0][0].cpu().detach().numpy(),cmap='gray')
# plt.show()
# plt.imshow(hx3d[0][0].cpu().detach().numpy(),cmap='gray')
# plt.show()
# plt.imshow(hx4d[0][0].cpu().detach().numpy(),cmap='gray')
# plt.show()
# plt.imshow(hx5d[0][0].cpu().detach().numpy(),cmap='gray')
# plt.show()
# plt.imshow(hx6[0][0].cpu().detach().numpy(),cmap='gray')
# plt.show()
return [F.sigmoid(d1), F.sigmoid(d2), F.sigmoid(d3), F.sigmoid(d4), F.sigmoid(d5), F.sigmoid(d6)],[hx1d,hx2d,hx3d,hx4d,hx5d,hx6]