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myNetwork_rcil.py
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myNetwork_rcil.py
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import copy
import math
import os
from functools import partial, reduce
import torch
import torch.nn as nn
import torch.nn.functional as F
from torch import distributed
from torch.nn import init
import inplace_abn
import models_rcil
from inplace_abn import ABN, InPlaceABN, InPlaceABNSync
from modules_rcil import DeeplabV3
def make_model_rcil(opts, classes=None):
if opts.norm_act == 'iabn_sync':
# norm = partial(InPlaceABNSync, activation="leaky_relu", activation_param=.01)
norm = partial(InPlaceABNSync, activation="leaky_relu", activation_param=1.)
elif opts.norm_act == 'iabn':
norm = partial(InPlaceABN, activation="leaky_relu", activation_param=.01)
elif opts.norm_act == 'abn':
norm = partial(ABN, activation="leaky_relu", activation_param=.01)
else:
norm = nn.BatchNorm2d # not synchronized, can be enabled with apex
if opts.norm_act == "iabn_sync_test":
opts.norm_act = "iabn_sync"
body = models_rcil.__dict__[f'net_{opts.backbone}'](norm_act=norm, output_stride=opts.output_stride)
if not opts.no_pretrained:
pretrained_path = os.path.join(opts.code_directory, f'pretrained/{opts.backbone}_{opts.norm_act}.pth.tar')
pre_dict = torch.load(pretrained_path, map_location='cpu')
for key in copy.deepcopy(list(pre_dict['state_dict'].keys())):
pre_dict['state_dict'][key[7:]] = pre_dict['state_dict'].pop(key)
del pre_dict['state_dict']['classifier.fc.weight']
del pre_dict['state_dict']['classifier.fc.bias']
load_dict = pre_dict['state_dict']
#########zhangcb change, load pretrained model to dual branch
new_load_dict = {}
for key in load_dict.keys():
if 'conv2' in key:
name = key
new_name = name.replace('conv2', 'conv2_new')
new_load_dict[new_name] = load_dict[key]
if 'bn2' in key:
name = key
new_name = name.replace('bn2', 'bn2_new')
# new_name = name.replace('bn2', 'bn2_new')
new_load_dict[new_name] = load_dict[key]
if 'map_convs' in key:
name = key
new_name = name.replace('map_convs', 'map_convs_new')
new_load_dict[new_name] = load_dict[key]
if 'map_bn' in key:
name = key
new_name = name.replace('map_bn', 'map_bn_new')
new_load_dict[new_name] = load_dict[key]
for k, v in new_load_dict.items():
load_dict[k] = v
#######################
body.load_state_dict(load_dict)
del pre_dict # free memory
head_channels = 256
head = DeeplabV3(
body.out_channels,
head_channels,
256,
norm_act=norm,
out_stride=opts.output_stride,
pooling_size=opts.pooling
)
if classes is not None:
model = IncrementalSegmentationModule(
body,
head,
head_channels,
classes=classes,
fusion_mode=opts.fusion_mode,
nb_background_modes=opts.nb_background_modes,
multimodal_fusion=opts.multimodal_fusion,
use_cosine=opts.cosine,
disable_background=opts.disable_background,
only_base_weights=opts.base_weights,
opts=opts
)
else:
model = SegmentationModule(body, head, head_channels, opts.num_classes, opts.fusion_mode)
return model
def flip(x, dim):
indices = [slice(None)] * x.dim()
indices[dim] = torch.arange(x.size(dim) - 1, -1, -1, dtype=torch.long, device=x.device)
return x[tuple(indices)]
class IncrementalSegmentationModule(nn.Module):
def __init__(
self,
body,
head,
head_channels,
classes,
ncm=False,
fusion_mode="mean",
nb_background_modes=1,
multimodal_fusion="sum",
use_cosine=False,
disable_background=False,
only_base_weights=False,
opts=None
):
super(IncrementalSegmentationModule, self).__init__()
self.body = body
self.head = head
# classes must be a list where [n_class_task[i] for i in tasks]
assert isinstance(classes, list), \
"Classes must be a list where to every index correspond the num of classes for that task"
use_bias = not use_cosine
if nb_background_modes > 1:
classes[0] -= 1
classes = [nb_background_modes] + classes
if only_base_weights:
classes = [classes[0]]
if opts.dataset == "cityscapes_domain":
classes = [opts.num_classes]
self.cls = nn.ModuleList([nn.Conv2d(head_channels, c, 1, bias=use_bias) for c in classes])
self.classes = classes
self.head_channels = head_channels
self.tot_classes = reduce(lambda a, b: a + b, self.classes)
self.means = None
self.multi_modal_background = nb_background_modes > 1
self.disable_background = disable_background
self.nb_background_modes = nb_background_modes
self.multimodal_fusion = multimodal_fusion
self.use_cosine = use_cosine
if use_cosine:
self.scalar = nn.Parameter(torch.tensor(1.)).float()
assert not self.multi_modal_background
else:
self.scalar = None
self.in_eval = False
def align_weight(self, align_type):
old_weight_norm = self._compute_weights_norm(self.cls[:-1], only=align_type)
new_weight_norm = self._compute_weights_norm(self.cls[-1:])
gamma = old_weight_norm / new_weight_norm
self.cls[-1].weight.data = gamma * self.cls[-1].weight.data
def _compute_weights_norm(self, convs, only="all"):
c = 0
s = 0.
for i, conv in enumerate(convs):
w = conv.weight.data[..., 0, 0]
if only == "old" and i == 0:
w = w[1:]
elif only == "background" and i == 0:
w = w[:1]
s += w.norm(dim=1).sum()
c += w.shape[0]
return s / c
def _network(self, x, ret_intermediate=False, only_bg=False):
x_b, attentions, branch1_x, branch2_x = self.body(x)
x_pl, decoder_old, decoder_new, decoder_add = self.head(x_b)
out = []
if self.use_cosine:
x_clf = x_pl.permute(0, 2, 3, 1)
x_clf = x_clf.reshape(x_pl.shape[0] * x_pl.shape[2] * x_pl.shape[3], x_pl.shape[1])
x_clf = F.normalize(x_clf, dim=1, p=2)
x_clf = x_clf.view(x_pl.shape[0], x_pl.shape[2], x_pl.shape[3], x_pl.shape[1])
x_clf = x_clf.permute(0, 3, 1, 2)
else:
x_clf = x_pl
if only_bg:
return self.cls[0](x_pl)
else:
for i, mod in enumerate(self.cls):
if i == 0 and self.multi_modal_background:
out.append(self.fusion(mod(x_pl)))
elif self.use_cosine:
w = F.normalize(mod.weight, dim=1, p=2)
out.append(F.conv2d(x_pl, w))
else:
out.append(mod(x_pl))
x_o = torch.cat(out, dim=1)
if self.disable_background and self.in_eval:
x_o[:, 0] = 0.
if ret_intermediate:
return x_o, x_b, x_pl, attentions, branch1_x, branch2_x, decoder_old, decoder_new, decoder_add
return x_o
def fusion(self, tensors):
if self.multimodal_fusion == "sum":
return tensors.sum(dim=1, keepdims=True)
elif self.multimodal_fusion == "mean":
return tensors.mean(dim=1, keepdims=True)
elif self.multimodal_fusion == "max":
return tensors.max(dim=1, keepdims=True)[0]
elif self.multimodal_fusion == "softmax":
return (F.softmax(tensors, dim=1) * tensors).sum(dim=1, keepdims=True)
else:
raise NotImplementedError(
f"Unknown fusion mode for multi-modality: {self.multimodal_fusion}."
)
def init_new_classifier(self, device):
cls = self.cls[-1]
if self.multi_modal_background:
imprinting_w = self.cls[0].weight.sum(dim=0)
bkg_bias = self.cls[0].bias.sum(dim=0)
else:
imprinting_w = self.cls[0].weight[0]
if not self.use_cosine:
bkg_bias = self.cls[0].bias[0]
if not self.use_cosine:
bias_diff = torch.log(torch.FloatTensor([self.classes[-1] + 1])).to(device)
new_bias = (bkg_bias - bias_diff)
cls.weight.data.copy_(imprinting_w)
if not self.use_cosine:
cls.bias.data.copy_(new_bias)
if self.multi_modal_background:
self.cls[0].bias.data.copy_(new_bias.squeeze(0))
else:
if not self.use_cosine:
self.cls[0].bias[0].data.copy_(new_bias.squeeze(0))
def init_new_classifier_multimodal(self, device, train_loader, init_type):
print("Init new multimodal classifier")
winners = torch.zeros(self.nb_background_modes,
self.classes[-1]).to(device, dtype=torch.long)
nb_old_classes = sum(self.classes[1:-1]) + 1
for images, labels in train_loader:
images = images.to(device, dtype=torch.float32)
labels = labels.to(device, dtype=torch.long)
modalities = self.forward(images, only_bg=True)[0].argmax(dim=1)
mask = (0 < labels) & (labels < 255)
modalities = modalities[mask].view(-1)
labels = labels[mask].view(-1)
winners.index_put_(
(modalities, labels - nb_old_classes),
torch.LongTensor([1]).expand_as(modalities).to(device),
accumulate=True
)
bias_diff = torch.log(torch.FloatTensor([self.classes[-1] + 1])).to(device)
if "_" in init_type:
init_type, to_reinit = init_type.split("_")
else:
to_reinit = None
for c in range(self.classes[-1]):
if init_type == "max":
modality = winners[:, c].argmax()
new_weight = self.cls[0].weight.data[modality]
new_bias = (self.cls[0].bias.data[modality] - bias_diff)[0]
elif init_type == "softmax":
modality = winners[:, c].argmax()
weighting = F.softmax(winners[:, c].float(), dim=0)
new_weight = (weighting[:, None, None, None] * self.cls[0].weight.data).sum(dim=0)
new_bias = (weighting * self.cls[0].bias.data).sum(dim=0)
else:
raise ValueError(f"Unknown multimodal init type: {init_type}.")
self.cls[-1].weight.data[c].copy_(new_weight)
self.cls[-1].bias.data[c].copy_(new_bias)
self.cls[0].bias.data[modality].copy_(new_bias)
if to_reinit is not None:
if to_reinit == "init":
init.kaiming_uniform_(self.cls[0].weights.data[modality], a=math.sqrt(5))
fan_in, _ = init._calculate_fan_in_and_fan_out(self.weight)
bound = 1 / math.sqrt(fan_in)
init.uniform_(self.cls[0].bias.data[modality], -bound, bound)
elif to_reinit == "remove":
self.cls[0].bias.data = torch.cat(
(self.cls[0].bias.data[:modality], self.cls[0].bias.data[modality + 1:])
)
def forward(self, x, scales=None, do_flip=False, ret_intermediate=False, only_bg=False):
out_size = x.shape[-2:]
out = self._network(x, ret_intermediate, only_bg=only_bg)
sem_logits_small = out[0] if ret_intermediate else out
sem_logits = F.interpolate(
sem_logits_small, size=out_size, mode="bilinear", align_corners=False
)
if ret_intermediate:
return sem_logits, {
"body": out[1],
"pre_logits": out[2],
"attentions": out[3] + [out[2]],
"branch_old": out[4],
"branch_new": out[5],
"sem_logits_small": sem_logits_small,
"decoder_old": out[6],
"decoder_new": out[7],
"decoder_add": out[8]
}
return sem_logits, {}
def fix_bn(self):
for m in self.modules():
if isinstance(m, nn.BatchNorm2d) or isinstance(m, inplace_abn.ABN):
m.eval()
m.weight.requires_grad = False
m.bias.requires_grad = False