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UniControl-Demo / annotator /uniformer /mmdet /models /backbones /hrnet.py

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	import torch.nn as nn
	from mmcv.cnn import (build_conv_layer, build_norm_layer, constant_init,
	kaiming_init)
	from mmcv.runner import load_checkpoint
	from torch.nn.modules.batchnorm import _BatchNorm

	from mmdet.utils import get_root_logger
	from ..builder import BACKBONES
	from .resnet import BasicBlock, Bottleneck


	class HRModule(nn.Module):
	"""High-Resolution Module for HRNet.

	In this module, every branch has 4 BasicBlocks/Bottlenecks. Fusion/Exchange
	is in this module.
	"""

	def __init__(self,
	num_branches,
	blocks,
	num_blocks,
	in_channels,
	num_channels,
	multiscale_output=True,
	with_cp=False,
	conv_cfg=None,
	norm_cfg=dict(type='BN')):
	super(HRModule, self).__init__()
	self._check_branches(num_branches, num_blocks, in_channels,
	num_channels)

	self.in_channels = in_channels
	self.num_branches = num_branches

	self.multiscale_output = multiscale_output
	self.norm_cfg = norm_cfg
	self.conv_cfg = conv_cfg
	self.with_cp = with_cp
	self.branches = self._make_branches(num_branches, blocks, num_blocks,
	num_channels)
	self.fuse_layers = self._make_fuse_layers()
	self.relu = nn.ReLU(inplace=False)

	def _check_branches(self, num_branches, num_blocks, in_channels,
	num_channels):
	if num_branches != len(num_blocks):
	error_msg = f'NUM_BRANCHES({num_branches}) ' \
	f'!= NUM_BLOCKS({len(num_blocks)})'
	raise ValueError(error_msg)

	if num_branches != len(num_channels):
	error_msg = f'NUM_BRANCHES({num_branches}) ' \
	f'!= NUM_CHANNELS({len(num_channels)})'
	raise ValueError(error_msg)

	if num_branches != len(in_channels):
	error_msg = f'NUM_BRANCHES({num_branches}) ' \
	f'!= NUM_INCHANNELS({len(in_channels)})'
	raise ValueError(error_msg)

	def _make_one_branch(self,
	branch_index,
	block,
	num_blocks,
	num_channels,
	stride=1):
	downsample = None
	if stride != 1 or \
	self.in_channels[branch_index] != \
	num_channels[branch_index] * block.expansion:
	downsample = nn.Sequential(
	build_conv_layer(
	self.conv_cfg,
	self.in_channels[branch_index],
	num_channels[branch_index] * block.expansion,
	kernel_size=1,
	stride=stride,
	bias=False),
	build_norm_layer(self.norm_cfg, num_channels[branch_index] *
	block.expansion)[1])

	layers = []
	layers.append(
	block(
	self.in_channels[branch_index],
	num_channels[branch_index],
	stride,
	downsample=downsample,
	with_cp=self.with_cp,
	norm_cfg=self.norm_cfg,
	conv_cfg=self.conv_cfg))
	self.in_channels[branch_index] = \
	num_channels[branch_index] * block.expansion
	for i in range(1, num_blocks[branch_index]):
	layers.append(
	block(
	self.in_channels[branch_index],
	num_channels[branch_index],
	with_cp=self.with_cp,
	norm_cfg=self.norm_cfg,
	conv_cfg=self.conv_cfg))

	return nn.Sequential(*layers)

	def _make_branches(self, num_branches, block, num_blocks, num_channels):
	branches = []

	for i in range(num_branches):
	branches.append(
	self._make_one_branch(i, block, num_blocks, num_channels))

	return nn.ModuleList(branches)

	def _make_fuse_layers(self):
	if self.num_branches == 1:
	return None

	num_branches = self.num_branches
	in_channels = self.in_channels
	fuse_layers = []
	num_out_branches = num_branches if self.multiscale_output else 1
	for i in range(num_out_branches):
	fuse_layer = []
	for j in range(num_branches):
	if j > i:
	fuse_layer.append(
	nn.Sequential(
	build_conv_layer(
	self.conv_cfg,
	in_channels[j],
	in_channels[i],
	kernel_size=1,
	stride=1,
	padding=0,
	bias=False),
	build_norm_layer(self.norm_cfg, in_channels[i])[1],
	nn.Upsample(
	scale_factor=2**(j - i), mode='nearest')))
	elif j == i:
	fuse_layer.append(None)
	else:
	conv_downsamples = []
	for k in range(i - j):
	if k == i - j - 1:
	conv_downsamples.append(
	nn.Sequential(
	build_conv_layer(
	self.conv_cfg,
	in_channels[j],
	in_channels[i],
	kernel_size=3,
	stride=2,
	padding=1,
	bias=False),
	build_norm_layer(self.norm_cfg,
	in_channels[i])[1]))
	else:
	conv_downsamples.append(
	nn.Sequential(
	build_conv_layer(
	self.conv_cfg,
	in_channels[j],
	in_channels[j],
	kernel_size=3,
	stride=2,
	padding=1,
	bias=False),
	build_norm_layer(self.norm_cfg,
	in_channels[j])[1],
	nn.ReLU(inplace=False)))
	fuse_layer.append(nn.Sequential(*conv_downsamples))
	fuse_layers.append(nn.ModuleList(fuse_layer))

	return nn.ModuleList(fuse_layers)

	def forward(self, x):
	"""Forward function."""
	if self.num_branches == 1:
	return [self.branches[0](x[0])]

	for i in range(self.num_branches):
	x[i] = self.branches[i](x[i])

	x_fuse = []
	for i in range(len(self.fuse_layers)):
	y = 0
	for j in range(self.num_branches):
	if i == j:
	y += x[j]
	else:
	y += self.fuse_layers[i][j](x[j])
	x_fuse.append(self.relu(y))
	return x_fuse


	@BACKBONES.register_module()
	class HRNet(nn.Module):
	"""HRNet backbone.

	High-Resolution Representations for Labeling Pixels and Regions
	arXiv: https://arxiv.org/abs/1904.04514

	Args:
	extra (dict): detailed configuration for each stage of HRNet.
	in_channels (int): Number of input image channels. Default: 3.
	conv_cfg (dict): dictionary to construct and config conv layer.
	norm_cfg (dict): dictionary to construct and config norm layer.
	norm_eval (bool): Whether to set norm layers to eval mode, namely,
	freeze running stats (mean and var). Note: Effect on Batch Norm
	and its variants only.
	with_cp (bool): Use checkpoint or not. Using checkpoint will save some
	memory while slowing down the training speed.
	zero_init_residual (bool): whether to use zero init for last norm layer
	in resblocks to let them behave as identity.

	Example:
	>>> from mmdet.models import HRNet
	>>> import torch
	>>> extra = dict(
	>>> stage1=dict(
	>>> num_modules=1,
	>>> num_branches=1,
	>>> block='BOTTLENECK',
	>>> num_blocks=(4, ),
	>>> num_channels=(64, )),
	>>> stage2=dict(
	>>> num_modules=1,
	>>> num_branches=2,
	>>> block='BASIC',
	>>> num_blocks=(4, 4),
	>>> num_channels=(32, 64)),
	>>> stage3=dict(
	>>> num_modules=4,
	>>> num_branches=3,
	>>> block='BASIC',
	>>> num_blocks=(4, 4, 4),
	>>> num_channels=(32, 64, 128)),
	>>> stage4=dict(
	>>> num_modules=3,
	>>> num_branches=4,
	>>> block='BASIC',
	>>> num_blocks=(4, 4, 4, 4),
	>>> num_channels=(32, 64, 128, 256)))
	>>> self = HRNet(extra, in_channels=1)
	>>> self.eval()
	>>> inputs = torch.rand(1, 1, 32, 32)
	>>> level_outputs = self.forward(inputs)
	>>> for level_out in level_outputs:
	... print(tuple(level_out.shape))
	(1, 32, 8, 8)
	(1, 64, 4, 4)
	(1, 128, 2, 2)
	(1, 256, 1, 1)
	"""

	blocks_dict = {'BASIC': BasicBlock, 'BOTTLENECK': Bottleneck}

	def __init__(self,
	extra,
	in_channels=3,
	conv_cfg=None,
	norm_cfg=dict(type='BN'),
	norm_eval=True,
	with_cp=False,
	zero_init_residual=False):
	super(HRNet, self).__init__()
	self.extra = extra
	self.conv_cfg = conv_cfg
	self.norm_cfg = norm_cfg
	self.norm_eval = norm_eval
	self.with_cp = with_cp
	self.zero_init_residual = zero_init_residual

	# stem net
	self.norm1_name, norm1 = build_norm_layer(self.norm_cfg, 64, postfix=1)
	self.norm2_name, norm2 = build_norm_layer(self.norm_cfg, 64, postfix=2)

	self.conv1 = build_conv_layer(
	self.conv_cfg,
	in_channels,
	64,
	kernel_size=3,
	stride=2,
	padding=1,
	bias=False)

	self.add_module(self.norm1_name, norm1)
	self.conv2 = build_conv_layer(
	self.conv_cfg,
	64,
	64,
	kernel_size=3,
	stride=2,
	padding=1,
	bias=False)

	self.add_module(self.norm2_name, norm2)
	self.relu = nn.ReLU(inplace=True)

	# stage 1
	self.stage1_cfg = self.extra['stage1']
	num_channels = self.stage1_cfg['num_channels'][0]
	block_type = self.stage1_cfg['block']
	num_blocks = self.stage1_cfg['num_blocks'][0]

	block = self.blocks_dict[block_type]
	stage1_out_channels = num_channels * block.expansion
	self.layer1 = self._make_layer(block, 64, num_channels, num_blocks)

	# stage 2
	self.stage2_cfg = self.extra['stage2']
	num_channels = self.stage2_cfg['num_channels']
	block_type = self.stage2_cfg['block']

	block = self.blocks_dict[block_type]
	num_channels = [channel * block.expansion for channel in num_channels]
	self.transition1 = self._make_transition_layer([stage1_out_channels],
	num_channels)
	self.stage2, pre_stage_channels = self._make_stage(
	self.stage2_cfg, num_channels)

	# stage 3
	self.stage3_cfg = self.extra['stage3']
	num_channels = self.stage3_cfg['num_channels']
	block_type = self.stage3_cfg['block']

	block = self.blocks_dict[block_type]
	num_channels = [channel * block.expansion for channel in num_channels]
	self.transition2 = self._make_transition_layer(pre_stage_channels,
	num_channels)
	self.stage3, pre_stage_channels = self._make_stage(
	self.stage3_cfg, num_channels)

	# stage 4
	self.stage4_cfg = self.extra['stage4']
	num_channels = self.stage4_cfg['num_channels']
	block_type = self.stage4_cfg['block']

	block = self.blocks_dict[block_type]
	num_channels = [channel * block.expansion for channel in num_channels]
	self.transition3 = self._make_transition_layer(pre_stage_channels,
	num_channels)
	self.stage4, pre_stage_channels = self._make_stage(
	self.stage4_cfg, num_channels)

	@property
	def norm1(self):
	"""nn.Module: the normalization layer named "norm1" """
	return getattr(self, self.norm1_name)

	@property
	def norm2(self):
	"""nn.Module: the normalization layer named "norm2" """
	return getattr(self, self.norm2_name)

	def _make_transition_layer(self, num_channels_pre_layer,
	num_channels_cur_layer):
	num_branches_cur = len(num_channels_cur_layer)
	num_branches_pre = len(num_channels_pre_layer)

	transition_layers = []
	for i in range(num_branches_cur):
	if i < num_branches_pre:
	if num_channels_cur_layer[i] != num_channels_pre_layer[i]:
	transition_layers.append(
	nn.Sequential(
	build_conv_layer(
	self.conv_cfg,
	num_channels_pre_layer[i],
	num_channels_cur_layer[i],
	kernel_size=3,
	stride=1,
	padding=1,
	bias=False),
	build_norm_layer(self.norm_cfg,
	num_channels_cur_layer[i])[1],
	nn.ReLU(inplace=True)))
	else:
	transition_layers.append(None)
	else:
	conv_downsamples = []
	for j in range(i + 1 - num_branches_pre):
	in_channels = num_channels_pre_layer[-1]
	out_channels = num_channels_cur_layer[i] \
	if j == i - num_branches_pre else in_channels
	conv_downsamples.append(
	nn.Sequential(
	build_conv_layer(
	self.conv_cfg,
	in_channels,
	out_channels,
	kernel_size=3,
	stride=2,
	padding=1,
	bias=False),
	build_norm_layer(self.norm_cfg, out_channels)[1],
	nn.ReLU(inplace=True)))
	transition_layers.append(nn.Sequential(*conv_downsamples))

	return nn.ModuleList(transition_layers)

	def _make_layer(self, block, inplanes, planes, blocks, stride=1):
	downsample = None
	if stride != 1 or inplanes != planes * block.expansion:
	downsample = nn.Sequential(
	build_conv_layer(
	self.conv_cfg,
	inplanes,
	planes * block.expansion,
	kernel_size=1,
	stride=stride,
	bias=False),
	build_norm_layer(self.norm_cfg, planes * block.expansion)[1])

	layers = []
	layers.append(
	block(
	inplanes,
	planes,
	stride,
	downsample=downsample,
	with_cp=self.with_cp,
	norm_cfg=self.norm_cfg,
	conv_cfg=self.conv_cfg))
	inplanes = planes * block.expansion
	for i in range(1, blocks):
	layers.append(
	block(
	inplanes,
	planes,
	with_cp=self.with_cp,
	norm_cfg=self.norm_cfg,
	conv_cfg=self.conv_cfg))

	return nn.Sequential(*layers)

	def _make_stage(self, layer_config, in_channels, multiscale_output=True):
	num_modules = layer_config['num_modules']
	num_branches = layer_config['num_branches']
	num_blocks = layer_config['num_blocks']
	num_channels = layer_config['num_channels']
	block = self.blocks_dict[layer_config['block']]

	hr_modules = []
	for i in range(num_modules):
	# multi_scale_output is only used for the last module
	if not multiscale_output and i == num_modules - 1:
	reset_multiscale_output = False
	else:
	reset_multiscale_output = True

	hr_modules.append(
	HRModule(
	num_branches,
	block,
	num_blocks,
	in_channels,
	num_channels,
	reset_multiscale_output,
	with_cp=self.with_cp,
	norm_cfg=self.norm_cfg,
	conv_cfg=self.conv_cfg))

	return nn.Sequential(*hr_modules), in_channels

	def init_weights(self, pretrained=None):
	"""Initialize the weights in backbone.

	Args:
	pretrained (str, optional): Path to pre-trained weights.
	Defaults to None.
	"""
	if isinstance(pretrained, str):
	logger = get_root_logger()
	load_checkpoint(self, pretrained, strict=False, logger=logger)
	elif pretrained is None:
	for m in self.modules():
	if isinstance(m, nn.Conv2d):
	kaiming_init(m)
	elif isinstance(m, (_BatchNorm, nn.GroupNorm)):
	constant_init(m, 1)

	if self.zero_init_residual:
	for m in self.modules():
	if isinstance(m, Bottleneck):
	constant_init(m.norm3, 0)
	elif isinstance(m, BasicBlock):
	constant_init(m.norm2, 0)
	else:
	raise TypeError('pretrained must be a str or None')

	def forward(self, x):
	"""Forward function."""
	x = self.conv1(x)
	x = self.norm1(x)
	x = self.relu(x)
	x = self.conv2(x)
	x = self.norm2(x)
	x = self.relu(x)
	x = self.layer1(x)

	x_list = []
	for i in range(self.stage2_cfg['num_branches']):
	if self.transition1[i] is not None:
	x_list.append(self.transition1[i](x))
	else:
	x_list.append(x)
	y_list = self.stage2(x_list)

	x_list = []
	for i in range(self.stage3_cfg['num_branches']):
	if self.transition2[i] is not None:
	x_list.append(self.transition2[i](y_list[-1]))
	else:
	x_list.append(y_list[i])
	y_list = self.stage3(x_list)

	x_list = []
	for i in range(self.stage4_cfg['num_branches']):
	if self.transition3[i] is not None:
	x_list.append(self.transition3[i](y_list[-1]))
	else:
	x_list.append(y_list[i])
	y_list = self.stage4(x_list)

	return y_list

	def train(self, mode=True):
	"""Convert the model into training mode will keeping the normalization
	layer freezed."""
	super(HRNet, self).train(mode)
	if mode and self.norm_eval:
	for m in self.modules():
	# trick: eval have effect on BatchNorm only
	if isinstance(m, _BatchNorm):
	m.eval()