Spaces:

akhaliq
/

GPEN

Running

GPEN / lpips /__init__.py

AK391

files

2782137 over 2 years ago

No virus

6.16 kB


	from __future__ import absolute_import
	from __future__ import division
	from __future__ import print_function

	import numpy as np
	import torch
	# from torch.autograd import Variable

	from lpips.trainer import *
	from lpips.lpips import *

	# class PerceptualLoss(torch.nn.Module):
	# def __init__(self, model='lpips', net='alex', spatial=False, use_gpu=False, gpu_ids=[0], version='0.1'): # VGG using our perceptually-learned weights (LPIPS metric)
	# # def __init__(self, model='net', net='vgg', use_gpu=True): # "default" way of using VGG as a perceptual loss
	# super(PerceptualLoss, self).__init__()
	# print('Setting up Perceptual loss...')
	# self.use_gpu = use_gpu
	# self.spatial = spatial
	# self.gpu_ids = gpu_ids
	# self.model = dist_model.DistModel()
	# self.model.initialize(model=model, net=net, use_gpu=use_gpu, spatial=self.spatial, gpu_ids=gpu_ids, version=version)
	# print('...[%s] initialized'%self.model.name())
	# print('...Done')

	# def forward(self, pred, target, normalize=False):
	# """
	# Pred and target are Variables.
	# If normalize is True, assumes the images are between [0,1] and then scales them between [-1,+1]
	# If normalize is False, assumes the images are already between [-1,+1]

	# Inputs pred and target are Nx3xHxW
	# Output pytorch Variable N long
	# """

	# if normalize:
	# target = 2 * target - 1
	# pred = 2 * pred - 1

	# return self.model.forward(target, pred)

	def normalize_tensor(in_feat,eps=1e-10):
	norm_factor = torch.sqrt(torch.sum(in_feat**2,dim=1,keepdim=True))
	return in_feat/(norm_factor+eps)

	def l2(p0, p1, range=255.):
	return .5np.mean((p0 / range - p1 / range)*2)

	def psnr(p0, p1, peak=255.):
	return 10np.log10(peak2/np.mean((1.p0-1.p1)*2))

	def dssim(p0, p1, range=255.):
	from skimage.measure import compare_ssim
	return (1 - compare_ssim(p0, p1, data_range=range, multichannel=True)) / 2.

	def rgb2lab(in_img,mean_cent=False):
	from skimage import color
	img_lab = color.rgb2lab(in_img)
	if(mean_cent):
	img_lab[:,:,0] = img_lab[:,:,0]-50
	return img_lab

	def tensor2np(tensor_obj):
	# change dimension of a tensor object into a numpy array
	return tensor_obj[0].cpu().float().numpy().transpose((1,2,0))

	def np2tensor(np_obj):
	# change dimenion of np array into tensor array
	return torch.Tensor(np_obj[:, :, :, np.newaxis].transpose((3, 2, 0, 1)))

	def tensor2tensorlab(image_tensor,to_norm=True,mc_only=False):
	# image tensor to lab tensor
	from skimage import color

	img = tensor2im(image_tensor)
	img_lab = color.rgb2lab(img)
	if(mc_only):
	img_lab[:,:,0] = img_lab[:,:,0]-50
	if(to_norm and not mc_only):
	img_lab[:,:,0] = img_lab[:,:,0]-50
	img_lab = img_lab/100.

	return np2tensor(img_lab)

	def tensorlab2tensor(lab_tensor,return_inbnd=False):
	from skimage import color
	import warnings
	warnings.filterwarnings("ignore")

	lab = tensor2np(lab_tensor)*100.
	lab[:,:,0] = lab[:,:,0]+50

	rgb_back = 255.*np.clip(color.lab2rgb(lab.astype('float')),0,1)
	if(return_inbnd):
	# convert back to lab, see if we match
	lab_back = color.rgb2lab(rgb_back.astype('uint8'))
	mask = 1.*np.isclose(lab_back,lab,atol=2.)
	mask = np2tensor(np.prod(mask,axis=2)[:,:,np.newaxis])
	return (im2tensor(rgb_back),mask)
	else:
	return im2tensor(rgb_back)

	def load_image(path):
	if(path[-3:] == 'dng'):
	import rawpy
	with rawpy.imread(path) as raw:
	img = raw.postprocess()
	elif(path[-3:]=='bmp' or path[-3:]=='jpg' or path[-3:]=='png'):
	import cv2
	return cv2.imread(path)[:,:,::-1]
	else:
	img = (255*plt.imread(path)[:,:,:3]).astype('uint8')

	return img

	def rgb2lab(input):
	from skimage import color
	return color.rgb2lab(input / 255.)

	def tensor2im(image_tensor, imtype=np.uint8, cent=1., factor=255./2.):
	image_numpy = image_tensor[0].cpu().float().numpy()
	image_numpy = (np.transpose(image_numpy, (1, 2, 0)) + cent) * factor
	return image_numpy.astype(imtype)

	def im2tensor(image, imtype=np.uint8, cent=1., factor=255./2.):
	return torch.Tensor((image / factor - cent)
	[:, :, :, np.newaxis].transpose((3, 2, 0, 1)))

	def tensor2vec(vector_tensor):
	return vector_tensor.data.cpu().numpy()[:, :, 0, 0]


	def tensor2im(image_tensor, imtype=np.uint8, cent=1., factor=255./2.):
	# def tensor2im(image_tensor, imtype=np.uint8, cent=1., factor=1.):
	image_numpy = image_tensor[0].cpu().float().numpy()
	image_numpy = (np.transpose(image_numpy, (1, 2, 0)) + cent) * factor
	return image_numpy.astype(imtype)

	def im2tensor(image, imtype=np.uint8, cent=1., factor=255./2.):
	# def im2tensor(image, imtype=np.uint8, cent=1., factor=1.):
	return torch.Tensor((image / factor - cent)
	[:, :, :, np.newaxis].transpose((3, 2, 0, 1)))



	def voc_ap(rec, prec, use_07_metric=False):
	""" ap = voc_ap(rec, prec, [use_07_metric])
	Compute VOC AP given precision and recall.
	If use_07_metric is true, uses the
	VOC 07 11 point method (default:False).
	"""
	if use_07_metric:
	# 11 point metric
	ap = 0.
	for t in np.arange(0., 1.1, 0.1):
	if np.sum(rec >= t) == 0:
	p = 0
	else:
	p = np.max(prec[rec >= t])
	ap = ap + p / 11.
	else:
	# correct AP calculation
	# first append sentinel values at the end
	mrec = np.concatenate(([0.], rec, [1.]))
	mpre = np.concatenate(([0.], prec, [0.]))

	# compute the precision envelope
	for i in range(mpre.size - 1, 0, -1):
	mpre[i - 1] = np.maximum(mpre[i - 1], mpre[i])

	# to calculate area under PR curve, look for points
	# where X axis (recall) changes value
	i = np.where(mrec[1:] != mrec[:-1])[0]

	# and sum (\Delta recall) * prec
	ap = np.sum((mrec[i + 1] - mrec[i]) * mpre[i + 1])
	return ap