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CharacterGAN / netdissect /upsegmodel /models.py

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	import torch
	import torch.nn as nn
	import torch.nn.functional as F
	import torchvision
	from . import resnet, resnext
	try:
	from lib.nn import SynchronizedBatchNorm2d
	except ImportError:
	from torch.nn import BatchNorm2d as SynchronizedBatchNorm2d


	class SegmentationModuleBase(nn.Module):
	def __init__(self):
	super(SegmentationModuleBase, self).__init__()

	@staticmethod
	def pixel_acc(pred, label, ignore_index=-1):
	_, preds = torch.max(pred, dim=1)
	valid = (label != ignore_index).long()
	acc_sum = torch.sum(valid * (preds == label).long())
	pixel_sum = torch.sum(valid)
	acc = acc_sum.float() / (pixel_sum.float() + 1e-10)
	return acc

	@staticmethod
	def part_pixel_acc(pred_part, gt_seg_part, gt_seg_object, object_label, valid):
	mask_object = (gt_seg_object == object_label)
	_, pred = torch.max(pred_part, dim=1)
	acc_sum = mask_object * (pred == gt_seg_part)
	acc_sum = torch.sum(acc_sum.view(acc_sum.size(0), -1), dim=1)
	acc_sum = torch.sum(acc_sum * valid)
	pixel_sum = torch.sum(mask_object.view(mask_object.size(0), -1), dim=1)
	pixel_sum = torch.sum(pixel_sum * valid)
	return acc_sum, pixel_sum

	@staticmethod
	def part_loss(pred_part, gt_seg_part, gt_seg_object, object_label, valid):
	mask_object = (gt_seg_object == object_label)
	loss = F.nll_loss(pred_part, gt_seg_part * mask_object.long(), reduction='none')
	loss = loss * mask_object.float()
	loss = torch.sum(loss.view(loss.size(0), -1), dim=1)
	nr_pixel = torch.sum(mask_object.view(mask_object.shape[0], -1), dim=1)
	sum_pixel = (nr_pixel * valid).sum()
	loss = (loss * valid.float()).sum() / torch.clamp(sum_pixel, 1).float()
	return loss


	class SegmentationModule(SegmentationModuleBase):
	def __init__(self, net_enc, net_dec, labeldata, loss_scale=None):
	super(SegmentationModule, self).__init__()
	self.encoder = net_enc
	self.decoder = net_dec
	self.crit_dict = nn.ModuleDict()
	if loss_scale is None:
	self.loss_scale = {"object": 1, "part": 0.5, "scene": 0.25, "material": 1}
	else:
	self.loss_scale = loss_scale

	# criterion
	self.crit_dict["object"] = nn.NLLLoss(ignore_index=0) # ignore background 0
	self.crit_dict["material"] = nn.NLLLoss(ignore_index=0) # ignore background 0
	self.crit_dict["scene"] = nn.NLLLoss(ignore_index=-1) # ignore unlabelled -1

	# Label data - read from json
	self.labeldata = labeldata
	object_to_num = {k: v for v, k in enumerate(labeldata['object'])}
	part_to_num = {k: v for v, k in enumerate(labeldata['part'])}
	self.object_part = {object_to_num[k]:
	[part_to_num[p] for p in v]
	for k, v in labeldata['object_part'].items()}
	self.object_with_part = sorted(self.object_part.keys())
	self.decoder.object_part = self.object_part
	self.decoder.object_with_part = self.object_with_part

	def forward(self, feed_dict, *, seg_size=None):
	if seg_size is None: # training

	if feed_dict['source_idx'] == 0:
	output_switch = {"object": True, "part": True, "scene": True, "material": False}
	elif feed_dict['source_idx'] == 1:
	output_switch = {"object": False, "part": False, "scene": False, "material": True}
	else:
	raise ValueError

	pred = self.decoder(
	self.encoder(feed_dict['img'], return_feature_maps=True),
	output_switch=output_switch
	)

	# loss
	loss_dict = {}
	if pred['object'] is not None: # object
	loss_dict['object'] = self.crit_dict['object'](pred['object'], feed_dict['seg_object'])
	if pred['part'] is not None: # part
	part_loss = 0
	for idx_part, object_label in enumerate(self.object_with_part):
	part_loss += self.part_loss(
	pred['part'][idx_part], feed_dict['seg_part'],
	feed_dict['seg_object'], object_label, feed_dict['valid_part'][:, idx_part])
	loss_dict['part'] = part_loss
	if pred['scene'] is not None: # scene
	loss_dict['scene'] = self.crit_dict['scene'](pred['scene'], feed_dict['scene_label'])
	if pred['material'] is not None: # material
	loss_dict['material'] = self.crit_dict['material'](pred['material'], feed_dict['seg_material'])
	loss_dict['total'] = sum([loss_dict[k] * self.loss_scale[k] for k in loss_dict.keys()])

	# metric
	metric_dict= {}
	if pred['object'] is not None:
	metric_dict['object'] = self.pixel_acc(
	pred['object'], feed_dict['seg_object'], ignore_index=0)
	if pred['material'] is not None:
	metric_dict['material'] = self.pixel_acc(
	pred['material'], feed_dict['seg_material'], ignore_index=0)
	if pred['part'] is not None:
	acc_sum, pixel_sum = 0, 0
	for idx_part, object_label in enumerate(self.object_with_part):
	acc, pixel = self.part_pixel_acc(
	pred['part'][idx_part], feed_dict['seg_part'], feed_dict['seg_object'],
	object_label, feed_dict['valid_part'][:, idx_part])
	acc_sum += acc
	pixel_sum += pixel
	metric_dict['part'] = acc_sum.float() / (pixel_sum.float() + 1e-10)
	if pred['scene'] is not None:
	metric_dict['scene'] = self.pixel_acc(
	pred['scene'], feed_dict['scene_label'], ignore_index=-1)

	return {'metric': metric_dict, 'loss': loss_dict}
	else: # inference
	output_switch = {"object": True, "part": True, "scene": True, "material": True}
	pred = self.decoder(self.encoder(feed_dict['img'], return_feature_maps=True),
	output_switch=output_switch, seg_size=seg_size)
	return pred


	def conv3x3(in_planes, out_planes, stride=1, has_bias=False):
	"3x3 convolution with padding"
	return nn.Conv2d(in_planes, out_planes, kernel_size=3, stride=stride,
	padding=1, bias=has_bias)


	def conv3x3_bn_relu(in_planes, out_planes, stride=1):
	return nn.Sequential(
	conv3x3(in_planes, out_planes, stride),
	SynchronizedBatchNorm2d(out_planes),
	nn.ReLU(inplace=True),
	)


	class ModelBuilder:
	def __init__(self):
	pass

	# custom weights initialization
	@staticmethod
	def weights_init(m):
	classname = m.__class__.__name__
	if classname.find('Conv') != -1:
	nn.init.kaiming_normal_(m.weight.data, nonlinearity='relu')
	elif classname.find('BatchNorm') != -1:
	m.weight.data.fill_(1.)
	m.bias.data.fill_(1e-4)
	#elif classname.find('Linear') != -1:
	# m.weight.data.normal_(0.0, 0.0001)

	def build_encoder(self, arch='resnet50_dilated8', fc_dim=512, weights=''):
	pretrained = True if len(weights) == 0 else False
	if arch == 'resnet34':
	raise NotImplementedError
	orig_resnet = resnet.__dict__['resnet34'](pretrained=pretrained)
	net_encoder = Resnet(orig_resnet)
	elif arch == 'resnet34_dilated8':
	raise NotImplementedError
	orig_resnet = resnet.__dict__['resnet34'](pretrained=pretrained)
	net_encoder = ResnetDilated(orig_resnet,
	dilate_scale=8)
	elif arch == 'resnet34_dilated16':
	raise NotImplementedError
	orig_resnet = resnet.__dict__['resnet34'](pretrained=pretrained)
	net_encoder = ResnetDilated(orig_resnet,
	dilate_scale=16)
	elif arch == 'resnet50':
	orig_resnet = resnet.__dict__['resnet50'](pretrained=pretrained)
	net_encoder = Resnet(orig_resnet)
	elif arch == 'resnet101':
	orig_resnet = resnet.__dict__['resnet101'](pretrained=pretrained)
	net_encoder = Resnet(orig_resnet)
	elif arch == 'resnext101':
	orig_resnext = resnext.__dict__['resnext101'](pretrained=pretrained)
	net_encoder = Resnet(orig_resnext) # we can still use class Resnet
	else:
	raise Exception('Architecture undefined!')

	# net_encoder.apply(self.weights_init)
	if len(weights) > 0:
	# print('Loading weights for net_encoder')
	net_encoder.load_state_dict(
	torch.load(weights, map_location=lambda storage, loc: storage), strict=False)
	return net_encoder

	def build_decoder(self, nr_classes,
	arch='ppm_bilinear_deepsup', fc_dim=512,
	weights='', use_softmax=False):
	if arch == 'upernet_lite':
	net_decoder = UPerNet(
	nr_classes=nr_classes,
	fc_dim=fc_dim,
	use_softmax=use_softmax,
	fpn_dim=256)
	elif arch == 'upernet':
	net_decoder = UPerNet(
	nr_classes=nr_classes,
	fc_dim=fc_dim,
	use_softmax=use_softmax,
	fpn_dim=512)
	else:
	raise Exception('Architecture undefined!')

	net_decoder.apply(self.weights_init)
	if len(weights) > 0:
	# print('Loading weights for net_decoder')
	net_decoder.load_state_dict(
	torch.load(weights, map_location=lambda storage, loc: storage), strict=False)
	return net_decoder


	class Resnet(nn.Module):
	def __init__(self, orig_resnet):
	super(Resnet, self).__init__()

	# take pretrained resnet, except AvgPool and FC
	self.conv1 = orig_resnet.conv1
	self.bn1 = orig_resnet.bn1
	self.relu1 = orig_resnet.relu1
	self.conv2 = orig_resnet.conv2
	self.bn2 = orig_resnet.bn2
	self.relu2 = orig_resnet.relu2
	self.conv3 = orig_resnet.conv3
	self.bn3 = orig_resnet.bn3
	self.relu3 = orig_resnet.relu3
	self.maxpool = orig_resnet.maxpool
	self.layer1 = orig_resnet.layer1
	self.layer2 = orig_resnet.layer2
	self.layer3 = orig_resnet.layer3
	self.layer4 = orig_resnet.layer4

	def forward(self, x, return_feature_maps=False):
	conv_out = []

	x = self.relu1(self.bn1(self.conv1(x)))
	x = self.relu2(self.bn2(self.conv2(x)))
	x = self.relu3(self.bn3(self.conv3(x)))
	x = self.maxpool(x)

	x = self.layer1(x); conv_out.append(x);
	x = self.layer2(x); conv_out.append(x);
	x = self.layer3(x); conv_out.append(x);
	x = self.layer4(x); conv_out.append(x);

	if return_feature_maps:
	return conv_out
	return [x]


	# upernet
	class UPerNet(nn.Module):
	def __init__(self, nr_classes, fc_dim=4096,
	use_softmax=False, pool_scales=(1, 2, 3, 6),
	fpn_inplanes=(256,512,1024,2048), fpn_dim=256):
	# Lazy import so that compilation isn't needed if not being used.
	from .prroi_pool import PrRoIPool2D
	super(UPerNet, self).__init__()
	self.use_softmax = use_softmax

	# PPM Module
	self.ppm_pooling = []
	self.ppm_conv = []

	for scale in pool_scales:
	# we use the feature map size instead of input image size, so down_scale = 1.0
	self.ppm_pooling.append(PrRoIPool2D(scale, scale, 1.))
	self.ppm_conv.append(nn.Sequential(
	nn.Conv2d(fc_dim, 512, kernel_size=1, bias=False),
	SynchronizedBatchNorm2d(512),
	nn.ReLU(inplace=True)
	))
	self.ppm_pooling = nn.ModuleList(self.ppm_pooling)
	self.ppm_conv = nn.ModuleList(self.ppm_conv)
	self.ppm_last_conv = conv3x3_bn_relu(fc_dim + len(pool_scales)*512, fpn_dim, 1)

	# FPN Module
	self.fpn_in = []
	for fpn_inplane in fpn_inplanes[:-1]: # skip the top layer
	self.fpn_in.append(nn.Sequential(
	nn.Conv2d(fpn_inplane, fpn_dim, kernel_size=1, bias=False),
	SynchronizedBatchNorm2d(fpn_dim),
	nn.ReLU(inplace=True)
	))
	self.fpn_in = nn.ModuleList(self.fpn_in)

	self.fpn_out = []
	for i in range(len(fpn_inplanes) - 1): # skip the top layer
	self.fpn_out.append(nn.Sequential(
	conv3x3_bn_relu(fpn_dim, fpn_dim, 1),
	))
	self.fpn_out = nn.ModuleList(self.fpn_out)

	self.conv_fusion = conv3x3_bn_relu(len(fpn_inplanes) * fpn_dim, fpn_dim, 1)

	# background included. if ignore in loss, output channel 0 will not be trained.
	self.nr_scene_class, self.nr_object_class, self.nr_part_class, self.nr_material_class = \
	nr_classes['scene'], nr_classes['object'], nr_classes['part'], nr_classes['material']

	# input: PPM out, input_dim: fpn_dim
	self.scene_head = nn.Sequential(
	conv3x3_bn_relu(fpn_dim, fpn_dim, 1),
	nn.AdaptiveAvgPool2d(1),
	nn.Conv2d(fpn_dim, self.nr_scene_class, kernel_size=1, bias=True)
	)

	# input: Fusion out, input_dim: fpn_dim
	self.object_head = nn.Sequential(
	conv3x3_bn_relu(fpn_dim, fpn_dim, 1),
	nn.Conv2d(fpn_dim, self.nr_object_class, kernel_size=1, bias=True)
	)

	# input: Fusion out, input_dim: fpn_dim
	self.part_head = nn.Sequential(
	conv3x3_bn_relu(fpn_dim, fpn_dim, 1),
	nn.Conv2d(fpn_dim, self.nr_part_class, kernel_size=1, bias=True)
	)

	# input: FPN_2 (P2), input_dim: fpn_dim
	self.material_head = nn.Sequential(
	conv3x3_bn_relu(fpn_dim, fpn_dim, 1),
	nn.Conv2d(fpn_dim, self.nr_material_class, kernel_size=1, bias=True)
	)

	def forward(self, conv_out, output_switch=None, seg_size=None):

	output_dict = {k: None for k in output_switch.keys()}

	conv5 = conv_out[-1]
	input_size = conv5.size()
	ppm_out = [conv5]
	roi = [] # fake rois, just used for pooling
	for i in range(input_size[0]): # batch size
	roi.append(torch.Tensor([i, 0, 0, input_size[3], input_size[2]]).view(1, -1)) # b, x0, y0, x1, y1
	roi = torch.cat(roi, dim=0).type_as(conv5)
	ppm_out = [conv5]
	for pool_scale, pool_conv in zip(self.ppm_pooling, self.ppm_conv):
	ppm_out.append(pool_conv(F.interpolate(
	pool_scale(conv5, roi.detach()),
	(input_size[2], input_size[3]),
	mode='bilinear', align_corners=False)))
	ppm_out = torch.cat(ppm_out, 1)
	f = self.ppm_last_conv(ppm_out)

	if output_switch['scene']: # scene
	output_dict['scene'] = self.scene_head(f)

	if output_switch['object'] or output_switch['part'] or output_switch['material']:
	fpn_feature_list = [f]
	for i in reversed(range(len(conv_out) - 1)):
	conv_x = conv_out[i]
	conv_x = self.fpn_in[i](conv_x) # lateral branch

	f = F.interpolate(
	f, size=conv_x.size()[2:], mode='bilinear', align_corners=False) # top-down branch
	f = conv_x + f

	fpn_feature_list.append(self.fpn_out[i](f))
	fpn_feature_list.reverse() # [P2 - P5]

	# material
	if output_switch['material']:
	output_dict['material'] = self.material_head(fpn_feature_list[0])

	if output_switch['object'] or output_switch['part']:
	output_size = fpn_feature_list[0].size()[2:]
	fusion_list = [fpn_feature_list[0]]
	for i in range(1, len(fpn_feature_list)):
	fusion_list.append(F.interpolate(
	fpn_feature_list[i],
	output_size,
	mode='bilinear', align_corners=False))
	fusion_out = torch.cat(fusion_list, 1)
	x = self.conv_fusion(fusion_out)

	if output_switch['object']: # object
	output_dict['object'] = self.object_head(x)
	if output_switch['part']:
	output_dict['part'] = self.part_head(x)

	if self.use_softmax: # is True during inference
	# inference scene
	x = output_dict['scene']
	x = x.squeeze(3).squeeze(2)
	x = F.softmax(x, dim=1)
	output_dict['scene'] = x

	# inference object, material
	for k in ['object', 'material']:
	x = output_dict[k]
	x = F.interpolate(x, size=seg_size, mode='bilinear', align_corners=False)
	x = F.softmax(x, dim=1)
	output_dict[k] = x

	# inference part
	x = output_dict['part']
	x = F.interpolate(x, size=seg_size, mode='bilinear', align_corners=False)
	part_pred_list, head = [], 0
	for idx_part, object_label in enumerate(self.object_with_part):
	n_part = len(self.object_part[object_label])
	_x = F.interpolate(x[:, head: head + n_part], size=seg_size, mode='bilinear', align_corners=False)
	_x = F.softmax(_x, dim=1)
	part_pred_list.append(_x)
	head += n_part
	output_dict['part'] = part_pred_list

	else: # Training
	# object, scene, material
	for k in ['object', 'scene', 'material']:
	if output_dict[k] is None:
	continue
	x = output_dict[k]
	x = F.log_softmax(x, dim=1)
	if k == "scene": # for scene
	x = x.squeeze(3).squeeze(2)
	output_dict[k] = x
	if output_dict['part'] is not None:
	part_pred_list, head = [], 0
	for idx_part, object_label in enumerate(self.object_with_part):
	n_part = len(self.object_part[object_label])
	x = output_dict['part'][:, head: head + n_part]
	x = F.log_softmax(x, dim=1)
	part_pred_list.append(x)
	head += n_part
	output_dict['part'] = part_pred_list

	return output_dict