forked from mrq/DL-Art-School
97 lines
4.4 KiB
Python
97 lines
4.4 KiB
Python
import torch
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import torch.nn as nn
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import torch.nn.functional as F
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from torchvision import transforms
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from torchvision import utils as vutils
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import models.archs.panet.common as common
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from models.archs.panet.tools import extract_image_patches, \
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reduce_mean, reduce_sum, same_padding
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from utils.util import checkpoint
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class PyramidAttention(nn.Module):
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def __init__(self, level=5, res_scale=1, channel=64, reduction=2, ksize=3, stride=1, softmax_scale=10, average=True,
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conv=common.default_conv):
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super(PyramidAttention, self).__init__()
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self.ksize = ksize
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self.stride = stride
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self.res_scale = res_scale
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self.softmax_scale = softmax_scale
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self.scale = [1 - i / 10 for i in range(level)]
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self.average = average
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escape_NaN = torch.FloatTensor([1e-4])
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self.register_buffer('escape_NaN', escape_NaN)
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self.conv_match_L_base = common.BasicBlock(conv, channel, channel // reduction, 1, bn=False, act=nn.PReLU())
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self.conv_match = common.BasicBlock(conv, channel, channel // reduction, 1, bn=False, act=nn.PReLU())
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self.conv_assembly = common.BasicBlock(conv, channel, channel, 1, bn=False, act=nn.PReLU())
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def forward(self, input):
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res = input
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# theta
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match_base = self.conv_match_L_base(input)
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shape_base = list(res.size())
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input_groups = torch.split(match_base, 1, dim=0)
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# patch size for matching
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kernel = self.ksize
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# raw_w is for reconstruction
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raw_w = []
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# w is for matching
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w = []
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# build feature pyramid
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for i in range(len(self.scale)):
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ref = input
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if self.scale[i] != 1:
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ref = F.interpolate(input, scale_factor=self.scale[i], mode='bicubic')
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# feature transformation function f
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base = self.conv_assembly(ref)
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shape_input = base.shape
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# sampling
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raw_w_i = extract_image_patches(base, ksizes=[kernel, kernel],
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strides=[self.stride, self.stride],
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rates=[1, 1],
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padding='same') # [N, C*k*k, L]
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raw_w_i = raw_w_i.view(shape_input[0], shape_input[1], kernel, kernel, -1)
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raw_w_i = raw_w_i.permute(0, 4, 1, 2, 3) # raw_shape: [N, L, C, k, k]
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raw_w_i_groups = torch.split(raw_w_i, 1, dim=0)
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raw_w.append(raw_w_i_groups)
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# feature transformation function g
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ref_i = self.conv_match(ref)
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shape_ref = ref_i.shape
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# sampling
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w_i = extract_image_patches(ref_i, ksizes=[self.ksize, self.ksize],
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strides=[self.stride, self.stride],
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rates=[1, 1],
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padding='same')
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w_i = w_i.view(shape_ref[0], shape_ref[1], self.ksize, self.ksize, -1)
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w_i = w_i.permute(0, 4, 1, 2, 3) # w shape: [N, L, C, k, k]
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w_i_groups = torch.split(w_i, 1, dim=0)
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w.append(w_i_groups)
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y = []
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for idx, xi in enumerate(input_groups):
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# group in a filter
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wi = torch.cat([w[i][idx][0] for i in range(len(self.scale))], dim=0) # [L, C, k, k]
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# normalize
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max_wi = torch.max(torch.sqrt(reduce_sum(torch.pow(wi, 2),
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axis=[1, 2, 3],
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keepdim=True)),
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self.escape_NaN)
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wi_normed = wi / max_wi
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# matching
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xi = same_padding(xi, [self.ksize, self.ksize], [1, 1], [1, 1]) # xi: 1*c*H*W
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yi = F.conv2d(xi, wi_normed, stride=1) # [1, L, H, W] L = shape_ref[2]*shape_ref[3]
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yi = yi.view(1, wi.shape[0], shape_base[2], shape_base[3]) # (B=1, C=32*32, H=32, W=32)
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# softmax matching score
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yi = F.softmax(yi * self.softmax_scale, dim=1)
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if self.average == False:
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yi = (yi == yi.max(dim=1, keepdim=True)[0]).float()
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# deconv for patch pasting
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raw_wi = torch.cat([raw_w[i][idx][0] for i in range(len(self.scale))], dim=0)
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yi = F.conv_transpose2d(yi, raw_wi, stride=self.stride, padding=1) / 4.
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y.append(yi)
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y = torch.cat(y, dim=0) + res * self.res_scale # back to the mini-batch
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return y |