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DragGAN / stylegan2 /lpips /dist_model.py

aaronb

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	from __future__ import absolute_import

	import sys
	import numpy as np
	import torch
	from torch import nn
	import os
	from collections import OrderedDict
	from torch.autograd import Variable
	import itertools
	from .base_model import BaseModel
	from scipy.ndimage import zoom
	import fractions
	import functools
	import skimage.transform
	from tqdm import tqdm
	import urllib

	from IPython import embed

	from . import networks_basic as networks
	from . import util


	class DownloadProgressBar(tqdm):
	def update_to(self, b=1, bsize=1, tsize=None):
	if tsize is not None:
	self.total = tsize
	self.update(b * bsize - self.n)


	def get_path(base_path):
	BASE_DIR = os.path.join('checkpoints')

	save_path = os.path.join(BASE_DIR, base_path)
	if not os.path.exists(save_path):
	url = f"https://huggingface.co/aaronb/StyleGAN2/resolve/main/{base_path}"
	print(f'{base_path} not found')
	print('Try to download from huggingface: ', url)
	os.makedirs(os.path.dirname(save_path), exist_ok=True)
	download_url(url, save_path)
	print('Downloaded to ', save_path)
	return save_path


	def download_url(url, output_path):
	with DownloadProgressBar(unit='B', unit_scale=True,
	miniters=1, desc=url.split('/')[-1]) as t:
	urllib.request.urlretrieve(url, filename=output_path, reporthook=t.update_to)


	class DistModel(BaseModel):
	def name(self):
	return self.model_name

	def initialize(self, model='net-lin', net='alex', colorspace='Lab', pnet_rand=False, pnet_tune=False, model_path=None,
	use_gpu=True, printNet=False, spatial=False,
	is_train=False, lr=.0001, beta1=0.5, version='0.1', gpu_ids=[0]):
	'''
	INPUTS
	model - ['net-lin'] for linearly calibrated network
	['net'] for off-the-shelf network
	['L2'] for L2 distance in Lab colorspace
	['SSIM'] for ssim in RGB colorspace
	net - ['squeeze','alex','vgg']
	model_path - if None, will look in weights/[NET_NAME].pth
	colorspace - ['Lab','RGB'] colorspace to use for L2 and SSIM
	use_gpu - bool - whether or not to use a GPU
	printNet - bool - whether or not to print network architecture out
	spatial - bool - whether to output an array containing varying distances across spatial dimensions
	spatial_shape - if given, output spatial shape. if None then spatial shape is determined automatically via spatial_factor (see below).
	spatial_factor - if given, specifies upsampling factor relative to the largest spatial extent of a convolutional layer. if None then resized to size of input images.
	spatial_order - spline order of filter for upsampling in spatial mode, by default 1 (bilinear).
	is_train - bool - [True] for training mode
	lr - float - initial learning rate
	beta1 - float - initial momentum term for adam
	version - 0.1 for latest, 0.0 was original (with a bug)
	gpu_ids - int array - [0] by default, gpus to use
	'''
	BaseModel.initialize(self, use_gpu=use_gpu, gpu_ids=gpu_ids)

	self.model = model
	self.net = net
	self.is_train = is_train
	self.spatial = spatial
	self.gpu_ids = gpu_ids
	self.model_name = '%s [%s]' % (model, net)

	if(self.model == 'net-lin'): # pretrained net + linear layer
	self.net = networks.PNetLin(pnet_rand=pnet_rand, pnet_tune=pnet_tune, pnet_type=net,
	use_dropout=True, spatial=spatial, version=version, lpips=True)
	kw = {}
	if not use_gpu:
	kw['map_location'] = 'cpu'
	if(model_path is None):
	model_path = get_path('weights/v%s/%s.pth' % (version, net))

	if(not is_train):
	print('Loading model from: %s' % model_path)
	self.net.load_state_dict(torch.load(model_path, **kw), strict=False)

	elif(self.model == 'net'): # pretrained network
	self.net = networks.PNetLin(pnet_rand=pnet_rand, pnet_type=net, lpips=False)
	elif(self.model in ['L2', 'l2']):
	self.net = networks.L2(use_gpu=use_gpu, colorspace=colorspace) # not really a network, only for testing
	self.model_name = 'L2'
	elif(self.model in ['DSSIM', 'dssim', 'SSIM', 'ssim']):
	self.net = networks.DSSIM(use_gpu=use_gpu, colorspace=colorspace)
	self.model_name = 'SSIM'
	else:
	raise ValueError("Model [%s] not recognized." % self.model)

	self.parameters = list(self.net.parameters())

	if self.is_train: # training mode
	# extra network on top to go from distances (d0,d1) => predicted human judgment (h*)
	self.rankLoss = networks.BCERankingLoss()
	self.parameters += list(self.rankLoss.net.parameters())
	self.lr = lr
	self.old_lr = lr
	self.optimizer_net = torch.optim.Adam(self.parameters, lr=lr, betas=(beta1, 0.999))
	else: # test mode
	self.net.eval()

	if(use_gpu):
	self.net.to(gpu_ids[0])
	self.net = torch.nn.DataParallel(self.net, device_ids=gpu_ids)
	if(self.is_train):
	self.rankLoss = self.rankLoss.to(device=gpu_ids[0]) # just put this on GPU0

	if(printNet):
	print('---------- Networks initialized -------------')
	networks.print_network(self.net)
	print('-----------------------------------------------')

	def forward(self, in0, in1, retPerLayer=False):
	''' Function computes the distance between image patches in0 and in1
	INPUTS
	in0, in1 - torch.Tensor object of shape Nx3xXxY - image patch scaled to [-1,1]
	OUTPUT
	computed distances between in0 and in1
	'''

	return self.net.forward(in0, in1, retPerLayer=retPerLayer)

	# *** TRAINING FUNCTIONS ***
	def optimize_parameters(self):
	self.forward_train()
	self.optimizer_net.zero_grad()
	self.backward_train()
	self.optimizer_net.step()
	self.clamp_weights()

	def clamp_weights(self):
	for module in self.net.modules():
	if(hasattr(module, 'weight') and module.kernel_size == (1, 1)):
	module.weight.data = torch.clamp(module.weight.data, min=0)

	def set_input(self, data):
	self.input_ref = data['ref']
	self.input_p0 = data['p0']
	self.input_p1 = data['p1']
	self.input_judge = data['judge']

	if(self.use_gpu):
	self.input_ref = self.input_ref.to(device=self.gpu_ids[0])
	self.input_p0 = self.input_p0.to(device=self.gpu_ids[0])
	self.input_p1 = self.input_p1.to(device=self.gpu_ids[0])
	self.input_judge = self.input_judge.to(device=self.gpu_ids[0])

	self.var_ref = Variable(self.input_ref, requires_grad=True)
	self.var_p0 = Variable(self.input_p0, requires_grad=True)
	self.var_p1 = Variable(self.input_p1, requires_grad=True)

	def forward_train(self): # run forward pass
	# print(self.net.module.scaling_layer.shift)
	# print(torch.norm(self.net.module.net.slice1[0].weight).item(), torch.norm(self.net.module.lin0.model[1].weight).item())

	self.d0 = self.forward(self.var_ref, self.var_p0)
	self.d1 = self.forward(self.var_ref, self.var_p1)
	self.acc_r = self.compute_accuracy(self.d0, self.d1, self.input_judge)

	self.var_judge = Variable(1. * self.input_judge).view(self.d0.size())

	self.loss_total = self.rankLoss.forward(self.d0, self.d1, self.var_judge * 2. - 1.)

	return self.loss_total

	def backward_train(self):
	torch.mean(self.loss_total).backward()

	def compute_accuracy(self, d0, d1, judge):
	''' d0, d1 are Variables, judge is a Tensor '''
	d1_lt_d0 = (d1 < d0).cpu().data.numpy().flatten()
	judge_per = judge.cpu().numpy().flatten()
	return d1_lt_d0 * judge_per + (1 - d1_lt_d0) * (1 - judge_per)

	def get_current_errors(self):
	retDict = OrderedDict([('loss_total', self.loss_total.data.cpu().numpy()),
	('acc_r', self.acc_r)])

	for key in retDict.keys():
	retDict[key] = np.mean(retDict[key])

	return retDict

	def get_current_visuals(self):
	zoom_factor = 256 / self.var_ref.data.size()[2]

	ref_img = util.tensor2im(self.var_ref.data)
	p0_img = util.tensor2im(self.var_p0.data)
	p1_img = util.tensor2im(self.var_p1.data)

	ref_img_vis = zoom(ref_img, [zoom_factor, zoom_factor, 1], order=0)
	p0_img_vis = zoom(p0_img, [zoom_factor, zoom_factor, 1], order=0)
	p1_img_vis = zoom(p1_img, [zoom_factor, zoom_factor, 1], order=0)

	return OrderedDict([('ref', ref_img_vis),
	('p0', p0_img_vis),
	('p1', p1_img_vis)])

	def save(self, path, label):
	if(self.use_gpu):
	self.save_network(self.net.module, path, '', label)
	else:
	self.save_network(self.net, path, '', label)
	self.save_network(self.rankLoss.net, path, 'rank', label)

	def update_learning_rate(self, nepoch_decay):
	lrd = self.lr / nepoch_decay
	lr = self.old_lr - lrd

	for param_group in self.optimizer_net.param_groups:
	param_group['lr'] = lr

	print('update lr [%s] decay: %f -> %f' % (type, self.old_lr, lr))
	self.old_lr = lr


	def score_2afc_dataset(data_loader, func, name=''):
	''' Function computes Two Alternative Forced Choice (2AFC) score using
	distance function 'func' in dataset 'data_loader'
	INPUTS
	data_loader - CustomDatasetDataLoader object - contains a TwoAFCDataset inside
	func - callable distance function - calling d=func(in0,in1) should take 2
	pytorch tensors with shape Nx3xXxY, and return numpy array of length N
	OUTPUTS
	[0] - 2AFC score in [0,1], fraction of time func agrees with human evaluators
	[1] - dictionary with following elements
	d0s,d1s - N arrays containing distances between reference patch to perturbed patches
	gts - N array in [0,1], preferred patch selected by human evaluators
	(closer to "0" for left patch p0, "1" for right patch p1,
	"0.6" means 60pct people preferred right patch, 40pct preferred left)
	scores - N array in [0,1], corresponding to what percentage function agreed with humans
	CONSTS
	N - number of test triplets in data_loader
	'''

	d0s = []
	d1s = []
	gts = []

	for data in tqdm(data_loader.load_data(), desc=name):
	d0s += func(data['ref'], data['p0']).data.cpu().numpy().flatten().tolist()
	d1s += func(data['ref'], data['p1']).data.cpu().numpy().flatten().tolist()
	gts += data['judge'].cpu().numpy().flatten().tolist()

	d0s = np.array(d0s)
	d1s = np.array(d1s)
	gts = np.array(gts)
	scores = (d0s < d1s) * (1. - gts) + (d1s < d0s) * gts + (d1s == d0s) * .5

	return(np.mean(scores), dict(d0s=d0s, d1s=d1s, gts=gts, scores=scores))


	def score_jnd_dataset(data_loader, func, name=''):
	''' Function computes JND score using distance function 'func' in dataset 'data_loader'
	INPUTS
	data_loader - CustomDatasetDataLoader object - contains a JNDDataset inside
	func - callable distance function - calling d=func(in0,in1) should take 2
	pytorch tensors with shape Nx3xXxY, and return pytorch array of length N
	OUTPUTS
	[0] - JND score in [0,1], mAP score (area under precision-recall curve)
	[1] - dictionary with following elements
	ds - N array containing distances between two patches shown to human evaluator
	sames - N array containing fraction of people who thought the two patches were identical
	CONSTS
	N - number of test triplets in data_loader
	'''

	ds = []
	gts = []

	for data in tqdm(data_loader.load_data(), desc=name):
	ds += func(data['p0'], data['p1']).data.cpu().numpy().tolist()
	gts += data['same'].cpu().numpy().flatten().tolist()

	sames = np.array(gts)
	ds = np.array(ds)

	sorted_inds = np.argsort(ds)
	ds_sorted = ds[sorted_inds]
	sames_sorted = sames[sorted_inds]

	TPs = np.cumsum(sames_sorted)
	FPs = np.cumsum(1 - sames_sorted)
	FNs = np.sum(sames_sorted) - TPs

	precs = TPs / (TPs + FPs)
	recs = TPs / (TPs + FNs)
	score = util.voc_ap(recs, precs)

	return(score, dict(ds=ds, sames=sames))