| 1234567891011121314151617181920212223242526272829303132333435363738394041424344454647484950515253 |
- import torch
- import torch.nn.functional as F
- from torch.autograd import Variable
- from math import exp
- def l1_loss(network_output, gt):
- return torch.abs((network_output - gt)).mean()
- def l2_loss(network_output, gt):
- return ((network_output - gt) ** 2).mean()
- def gaussian(window_size, sigma):
- gauss = torch.Tensor([exp(-(x - window_size // 2) ** 2 / float(2 * sigma ** 2)) for x in range(window_size)])
- return gauss / gauss.sum()
- def create_window(window_size, channel):
- _1D_window = gaussian(window_size, 1.5).unsqueeze(1)
- _2D_window = _1D_window.mm(_1D_window.t()).float().unsqueeze(0).unsqueeze(0)
- window = Variable(_2D_window.expand(channel, 1, window_size, window_size).contiguous())
- return window
- def ssim(img1, img2, window_size=11, size_average=True):
- channel = img1.size(-3)
- window = create_window(window_size, channel)
- if img1.is_cuda:
- window = window.cuda(img1.get_device())
- window = window.type_as(img1)
- return _ssim(img1, img2, window, window_size, channel, size_average)
- def _ssim(img1, img2, window, window_size, channel, size_average=True):
- mu1 = F.conv2d(img1, window, padding=window_size // 2, groups=channel)
- mu2 = F.conv2d(img2, window, padding=window_size // 2, groups=channel)
- mu1_sq = mu1.pow(2)
- mu2_sq = mu2.pow(2)
- mu1_mu2 = mu1 * mu2
- sigma1_sq = F.conv2d(img1 * img1, window, padding=window_size // 2, groups=channel) - mu1_sq
- sigma2_sq = F.conv2d(img2 * img2, window, padding=window_size // 2, groups=channel) - mu2_sq
- sigma12 = F.conv2d(img1 * img2, window, padding=window_size // 2, groups=channel) - mu1_mu2
- C1 = 0.01 ** 2
- C2 = 0.03 ** 2
- ssim_map = ((2 * mu1_mu2 + C1) * (2 * sigma12 + C2)) / ((mu1_sq + mu2_sq + C1) * (sigma1_sq + sigma2_sq + C2))
- if size_average:
- return ssim_map.mean()
- else:
- return ssim_map.mean(1).mean(1).mean(1)
|
