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	import torch
	import numpy as np
	import torch.nn as nn
	import torch.nn.functional as F
	import torchvision.models as models

	device = torch.device("cuda" if torch.cuda.is_available() else "cpu")


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

	def forward(self, flow, gt, loss_mask):
	loss_map = (flow - gt.detach()) ** 2
	loss_map = (loss_map.sum(1, True) + 1e-6) ** 0.5
	return (loss_map * loss_mask)


	class Ternary(nn.Module):
	def __init__(self):
	super(Ternary, self).__init__()
	patch_size = 7
	out_channels = patch_size * patch_size
	self.w = np.eye(out_channels).reshape(
	(patch_size, patch_size, 1, out_channels))
	self.w = np.transpose(self.w, (3, 2, 0, 1))
	self.w = torch.tensor(self.w).float().to(device)

	def transform(self, img):
	patches = F.conv2d(img, self.w, padding=3, bias=None)
	transf = patches - img
	transf_norm = transf / torch.sqrt(0.81 + transf**2)
	return transf_norm

	def rgb2gray(self, rgb):
	r, g, b = rgb[:, 0:1, :, :], rgb[:, 1:2, :, :], rgb[:, 2:3, :, :]
	gray = 0.2989 * r + 0.5870 * g + 0.1140 * b
	return gray

	def hamming(self, t1, t2):
	dist = (t1 - t2) ** 2
	dist_norm = torch.mean(dist / (0.1 + dist), 1, True)
	return dist_norm

	def valid_mask(self, t, padding):
	n, _, h, w = t.size()
	inner = torch.ones(n, 1, h - 2 * padding, w - 2 * padding).type_as(t)
	mask = F.pad(inner, [padding] * 4)
	return mask

	def forward(self, img0, img1):
	img0 = self.transform(self.rgb2gray(img0))
	img1 = self.transform(self.rgb2gray(img1))
	return self.hamming(img0, img1) * self.valid_mask(img0, 1)


	class SOBEL(nn.Module):
	def __init__(self):
	super(SOBEL, self).__init__()
	self.kernelX = torch.tensor([
	[1, 0, -1],
	[2, 0, -2],
	[1, 0, -1],
	]).float()
	self.kernelY = self.kernelX.clone().T
	self.kernelX = self.kernelX.unsqueeze(0).unsqueeze(0).to(device)
	self.kernelY = self.kernelY.unsqueeze(0).unsqueeze(0).to(device)

	def forward(self, pred, gt):
	N, C, H, W = pred.shape[0], pred.shape[1], pred.shape[2], pred.shape[3]
	img_stack = torch.cat(
	[pred.reshape(NC, 1, H, W), gt.reshape(NC, 1, H, W)], 0)
	sobel_stack_x = F.conv2d(img_stack, self.kernelX, padding=1)
	sobel_stack_y = F.conv2d(img_stack, self.kernelY, padding=1)
	pred_X, gt_X = sobel_stack_x[:NC], sobel_stack_x[NC:]
	pred_Y, gt_Y = sobel_stack_y[:NC], sobel_stack_y[NC:]

	L1X, L1Y = torch.abs(pred_X-gt_X), torch.abs(pred_Y-gt_Y)
	loss = (L1X+L1Y)
	return loss

	class MeanShift(nn.Conv2d):
	def __init__(self, data_mean, data_std, data_range=1, norm=True):
	c = len(data_mean)
	super(MeanShift, self).__init__(c, c, kernel_size=1)
	std = torch.Tensor(data_std)
	self.weight.data = torch.eye(c).view(c, c, 1, 1)
	if norm:
	self.weight.data.div_(std.view(c, 1, 1, 1))
	self.bias.data = -1 * data_range * torch.Tensor(data_mean)
	self.bias.data.div_(std)
	else:
	self.weight.data.mul_(std.view(c, 1, 1, 1))
	self.bias.data = data_range * torch.Tensor(data_mean)
	self.requires_grad = False

	class VGGPerceptualLoss(torch.nn.Module):
	def __init__(self, rank=0):
	super(VGGPerceptualLoss, self).__init__()
	blocks = []
	pretrained = True
	self.vgg_pretrained_features = models.vgg19(pretrained=pretrained).features
	self.normalize = MeanShift([0.485, 0.456, 0.406], [0.229, 0.224, 0.225], norm=True).cuda()
	for param in self.parameters():
	param.requires_grad = False

	def forward(self, X, Y, indices=None):
	X = self.normalize(X)
	Y = self.normalize(Y)
	indices = [2, 7, 12, 21, 30]
	weights = [1.0/2.6, 1.0/4.8, 1.0/3.7, 1.0/5.6, 10/1.5]
	k = 0
	loss = 0
	for i in range(indices[-1]):
	X = self.vgg_pretrained_features[i](X)
	Y = self.vgg_pretrained_features[i](Y)
	if (i+1) in indices:
	loss += weights[k] * (X - Y.detach()).abs().mean() * 0.1
	k += 1
	return loss

	if __name__ == '__main__':
	img0 = torch.zeros(3, 3, 256, 256).float().to(device)
	img1 = torch.tensor(np.random.normal(
	0, 1, (3, 3, 256, 256))).float().to(device)
	ternary_loss = Ternary()
	print(ternary_loss(img0, img1).shape)