utils.py

"""
Copyright (C) 2018 NVIDIA Corporation.  All rights reserved.
Licensed under the CC BY-NC-SA 4.0 license (https://creativecommons.org/licenses/by-nc-sa/4.0/legalcode).
"""
import torch
#from torch.utils.serialization import load_lua
from torch.utils.data import DataLoader
from networks import Vgg16
from torch.autograd import Variable
from torch.optim import lr_scheduler
from torchvision import transforms
from data import ImageFilelist, ImageFolder, ImageFolder_Double
import torch.nn as nn
import os
import math
import torchvision.utils as vutils
import yaml
import numpy as np
import torch.nn.init as init
import time
import random

# Methods
# get_all_data_loaders      : primary data loader interface (load trainA, testA, trainB, testB)
# get_data_loader_list      : list-based data loader
# get_data_loader_folder    : folder-based data loader
# get_config                : load yaml file
# eformat                   :
# write_2images             : save output image
# prepare_sub_folder        : create checkpoints and images folders for saving outputs
# write_one_row_html        : write one row of the html file for output images
# write_html                : create the html file.
# write_loss
# slerp
# get_slerp_interp
# get_model_list
# load_vgg16
# load_inception
# vgg_preprocess
# get_scheduler
# weights_init

 
def get_all_data_loaders(conf):
    batch_size = conf['batch_size']
    num_workers = conf['num_workers']
    if 'new_size' in conf:
        new_size_a = new_size_b = conf['new_size']
    else:
        new_size_a = conf['new_size_a']
        new_size_b = conf['new_size_b']
    height = conf['crop_image_height']
    width = conf['crop_image_width']
    continuize_transforms = conf['continuize_transforms']

    train_loader_ab = get_data_loader_folder_double(os.path.join(conf['data_root'], 'trainA'), os.path.join(conf['data_root'], 'trainB'), 
												False, batch_size, False, new_size_a, False, num_workers, False, continuize_transforms=continuize_transforms)

    train_loader_aTbT = get_data_loader_folder_double(os.path.join(conf['data_root'], 'trainA'), os.path.join(conf['data_root'], 'trainB'),
												True, batch_size, False, new_size_a, False, num_workers, False, continuize_transforms=continuize_transforms)

    test_loader_ab = get_data_loader_folder_double(os.path.join(conf['data_root'], 'testA'), os.path.join(conf['data_root'], 'testB'),
                                                False, batch_size, False, new_size_a, False, num_workers, False, continuize_transforms=continuize_transforms)

    test_loader_aTbT = get_data_loader_folder_double(os.path.join(conf['data_root'], 'testA'), os.path.join(conf['data_root'], 'testB'),
                                                True, batch_size, False, new_size_a, False, num_workers, False, continuize_transforms=continuize_transforms)

    return train_loader_ab, train_loader_aTbT, test_loader_ab, test_loader_aTbT



def get_data_loader_folder_double(input_folder1, input_folder2, trans_func, batch_size, train, new_size, return_paths = False, num_workers=4, crop=False, specific_pretransform=None, continuize_transforms=False):
    transform = transforms.Compose([
        transforms.ToPILImage(),
        transforms.Resize(new_size),
        transforms.ToTensor(),
        transforms.Normalize((0.5,),(0.5,))])

    dataset = ImageFolder_Double(input_folder1, input_folder2, transform=transform, return_paths=return_paths, trans_func=trans_func, specific_pretransform=specific_pretransform, continuize_transforms=continuize_transforms)
    loader = DataLoader(dataset=dataset, batch_size=batch_size, shuffle=False, drop_last=True, num_workers=num_workers)
    return loader



def get_data_loader_folder(input_folder, trans_func, batch_size, train, new_size, return_paths = False, num_workers=4, crop=False):
    transform = transforms.Compose([
        transforms.ToPILImage(),
        transforms.Resize(new_size),
        transforms.ToTensor(),
        transforms.Normalize((0.5,),(0.5,))])

    dataset = ImageFolder(input_folder, transform=transform, return_paths=return_paths, trans_func=trans_func)
    loader = DataLoader(dataset=dataset, batch_size=batch_size, shuffle=False, drop_last=True, num_workers=num_workers)
    return loader

def get_config(config):
    with open(config, 'r') as stream:
        return yaml.load(stream)


def eformat(f, prec):
    s = "%.*e"%(prec, f)
    mantissa, exp = s.split('e')
    # add 1 to digits as 1 is taken by sign +/-
    return "%se%d"%(mantissa, int(exp))


#def __write_images(image_outputs, display_image_num, file_name):
#    image_outputs = [images.expand(-1, 3, -1, -1) for images in image_outputs] # expand gray-scale images to 3 channels
#    image_tensor = torch.cat([images[:display_image_num] for images in image_outputs], 0)
#    image_grid = vutils.make_grid(image_tensor.data, nrow=display_image_num, padding=0, normalize=True)
#    vutils.save_image(image_grid, file_name, nrow=1)


#def write_2images(image_outputs, display_image_num, image_directory, postfix, obj1, obj2):
#    n = len(image_outputs)
#    __write_images(image_outputs[0:n//2], display_image_num, '%s/gen_%s2%s_%s.jpg' % (image_directory, obj1, obj2, postfix))
#    __write_images(image_outputs[n//2:n], display_image_num, '%s/gen_%s2%s_%s.jpg' % (image_directory, obj2, obj1, postfix))


def write_2images(image_outputs, display_image_num, image_directory, postfix, obj):
    file_name = '%s/gen_%s_%s.jpg' % (image_directory, obj, postfix)
    image_outputs = [images.expand(-1, 3, -1, -1) for images in image_outputs] # expand gray-scale images to 3 channels                       
    image_tensor = torch.cat([images[:display_image_num] for images in image_outputs], 0)
    image_grid = vutils.make_grid(image_tensor.data, nrow=display_image_num, padding=0, normalize=True)
    vutils.save_image(image_grid, file_name, nrow=1)

def prepare_sub_folder(output_directory):
    image_directory = os.path.join(output_directory, 'images')
    if not os.path.exists(image_directory):
        print("Creating directory: {}".format(image_directory))
        os.makedirs(image_directory)
    checkpoint_directory = os.path.join(output_directory, 'checkpoints')
    if not os.path.exists(checkpoint_directory):
        print("Creating directory: {}".format(checkpoint_directory))
        os.makedirs(checkpoint_directory)
    return checkpoint_directory, image_directory


def write_one_row_html(html_file, iterations, img_filename, all_size):
    html_file.write("<h3>iteration [%d] (%s)</h3>" % (iterations,img_filename.split('/')[-1]))
    html_file.write("""
        <p><a href="%s">
          <img src="%s" style="width:%dpx">
        </a><br>
        <p>
        """ % (img_filename, img_filename, all_size))
    return


def write_html(filename, iterations, image_save_iterations, image_directory, all_size=1536):
    html_file = open(filename, "w")
    html_file.write('''
    <!DOCTYPE html>
    <html>
    <head>
      <title>Experiment name = %s</title>
      <meta http-equiv="refresh" content="30">
    </head>
    <body>
    ''' % os.path.basename(filename))
    html_file.write("<h3>current</h3>")
    write_one_row_html(html_file, iterations, '%s/gen_a_train_current.jpg' % (image_directory), all_size)
    write_one_row_html(html_file, iterations, '%s/gen_b_train_current.jpg' % (image_directory), all_size)
    for j in range(iterations, image_save_iterations-1, -1):
        if j % image_save_iterations == 0:
            write_one_row_html(html_file, j, '%s/gen_a_train_%08d.jpg' % (image_directory, j), all_size)
            write_one_row_html(html_file, j, '%s/gen_b_train_%08d.jpg' % (image_directory, j), all_size)
            write_one_row_html(html_file, j, '%s/gen__test_%08d.jpg' % (image_directory, j), all_size)
    html_file.write("</body></html>")
    html_file.close()


def write_loss(iterations, trainer, train_writer):
    members = [attr for attr in dir(trainer) \
               if not callable(getattr(trainer, attr)) and not attr.startswith("__") and ('loss' in attr or 'grad' in attr or 'nwd' in attr)]
    for m in members:
        train_writer.add_scalar(m, getattr(trainer, m), iterations + 1)


def slerp(val, low, high):
    """
    original: Animating Rotation with Quaternion Curves, Ken Shoemake
    https://arxiv.org/abs/1609.04468
    Code: https://github.com/soumith/dcgan.torch/issues/14, Tom White
    """
    omega = np.arccos(np.dot(low / np.linalg.norm(low), high / np.linalg.norm(high)))
    so = np.sin(omega)
    return np.sin((1.0 - val) * omega) / so * low + np.sin(val * omega) / so * high


def get_slerp_interp(nb_latents, nb_interp, z_dim):
    """
    modified from: PyTorch inference for "Progressive Growing of GANs" with CelebA snapshot
    https://github.com/ptrblck/prog_gans_pytorch_inference
    """

    latent_interps = np.empty(shape=(0, z_dim), dtype=np.float32)
    for _ in range(nb_latents):
        low = np.random.randn(z_dim)
        high = np.random.randn(z_dim)  # low + np.random.randn(512) * 0.7
        interp_vals = np.linspace(0, 1, num=nb_interp)
        latent_interp = np.array([slerp(v, low, high) for v in interp_vals],
                                 dtype=np.float32)
        latent_interps = np.vstack((latent_interps, latent_interp))

    return latent_interps[:, :, np.newaxis, np.newaxis]


# Get model list for resume
def get_model_list(dirname, key):
    if os.path.exists(dirname) is False:
        return None
    gen_models = [os.path.join(dirname, f) for f in os.listdir(dirname) if
                  os.path.isfile(os.path.join(dirname, f)) and key in f and ".pt" in f]
    if gen_models is None:
        return None
    gen_models.sort()
    last_model_name = gen_models[-1]
    return last_model_name


def load_vgg16(model_dir):
    """ Use the model from https://github.com/abhiskk/fast-neural-style/blob/master/neural_style/utils.py """
    if not os.path.exists(model_dir):
        os.mkdir(model_dir)
    if not os.path.exists(os.path.join(model_dir, 'vgg16.weight')):
        if not os.path.exists(os.path.join(model_dir, 'vgg16.t7')):
            os.system('wget https://www.dropbox.com/s/76l3rt4kyi3s8x7/vgg16.t7?dl=1 -O ' + os.path.join(model_dir, 'vgg16.t7'))
        vgglua = load_lua(os.path.join(model_dir, 'vgg16.t7'))
        vgg = Vgg16()
        for (src, dst) in zip(vgglua.parameters()[0], vgg.parameters()):
            dst.data[:] = src
        torch.save(vgg.state_dict(), os.path.join(model_dir, 'vgg16.weight'))
    vgg = Vgg16()
    vgg.load_state_dict(torch.load(os.path.join(model_dir, 'vgg16.weight')))
    return vgg

def load_inception(model_path):
    state_dict = torch.load(model_path)
    model = inception_v3(pretrained=False, transform_input=True)
    model.aux_logits = False
    num_ftrs = model.fc.in_features
    model.fc = nn.Linear(num_ftrs, state_dict['fc.weight'].size(0))
    model.load_state_dict(state_dict)
    for param in model.parameters():
        param.requires_grad = False
    return model

def vgg_preprocess(batch):
    tensortype = type(batch.data)
    (r, g, b) = torch.chunk(batch, 3, dim = 1)
    batch = torch.cat((b, g, r), dim = 1) # convert RGB to BGR
    batch = (batch + 1) * 255 * 0.5 # [-1, 1] -> [0, 255]
    mean = tensortype(batch.data.size()).cuda()
    mean[:, 0, :, :] = 103.939
    mean[:, 1, :, :] = 116.779
    mean[:, 2, :, :] = 123.680
    batch = batch.sub(Variable(mean)) # subtract mean
    return batch


def get_scheduler(optimizer, hyperparameters, iterations=-1):
    if 'lr_policy' not in hyperparameters or hyperparameters['lr_policy'] == 'constant':
        scheduler = None # constant scheduler
    elif hyperparameters['lr_policy'] == 'step':
        scheduler = lr_scheduler.StepLR(optimizer, step_size=hyperparameters['step_size'],
                                        gamma=hyperparameters['gamma'], last_epoch=iterations)
    else:
        return NotImplementedError('learning rate policy [%s] is not implemented', hyperparameters['lr_policy'])
    return scheduler


def weights_init(init_type='gaussian'):
    def init_fun(m):
        classname = m.__class__.__name__
        if (classname.find('Conv') == 0 or classname.find('Linear') == 0) and hasattr(m, 'weight'):
            # print m.__class__.__name__
            if init_type == 'gaussian':
                init.normal_(m.weight.data, 0.0, 0.02)
            elif init_type == 'xavier':
                init.xavier_normal_(m.weight.data, gain=math.sqrt(2))
            elif init_type == 'kaiming':
                init.kaiming_normal_(m.weight.data, a=0, mode='fan_in')
            elif init_type == 'orthogonal':
                init.orthogonal_(m.weight.data, gain=math.sqrt(2))
            elif init_type == 'default':
                pass
            else:
                assert 0, "Unsupported initialization: {}".format(init_type)
            if hasattr(m, 'bias') and m.bias is not None:
                init.constant_(m.bias.data, 0.0)

    return init_fun


class Timer:
    def __init__(self, msg):
        self.msg = msg
        self.start_time = None

    def __enter__(self):
        self.start_time = time.time()

    def __exit__(self, exc_type, exc_value, exc_tb):
        print(self.msg % (time.time() - self.start_time))


def pytorch03_to_pytorch04(state_dict_base, trainer_name):
    def __conversion_core(state_dict_base, trainer_name):
        state_dict = state_dict_base.copy()
        if trainer_name == 'STAR':
            for key, value in state_dict_base.items():
                if key.endswith(('enc_content.model.0.norm.running_mean',
                                 'enc_content.model.0.norm.running_var',
                                 'enc_content.model.1.norm.running_mean',
                                 'enc_content.model.1.norm.running_var',
                                 'enc_content.model.2.norm.running_mean',
                                 'enc_content.model.2.norm.running_var',
                                 'enc_content.model.3.model.0.model.1.norm.running_mean',
                                 'enc_content.model.3.model.0.model.1.norm.running_var',
                                 'enc_content.model.3.model.0.model.0.norm.running_mean',
                                 'enc_content.model.3.model.0.model.0.norm.running_var',
                                 'enc_content.model.3.model.1.model.1.norm.running_mean',
                                 'enc_content.model.3.model.1.model.1.norm.running_var',
                                 'enc_content.model.3.model.1.model.0.norm.running_mean',
                                 'enc_content.model.3.model.1.model.0.norm.running_var',
                                 'enc_content.model.3.model.2.model.1.norm.running_mean',
                                 'enc_content.model.3.model.2.model.1.norm.running_var',
                                 'enc_content.model.3.model.2.model.0.norm.running_mean',
                                 'enc_content.model.3.model.2.model.0.norm.running_var',
                                 'enc_content.model.3.model.3.model.1.norm.running_mean',
                                 'enc_content.model.3.model.3.model.1.norm.running_var',
                                 'enc_content.model.3.model.3.model.0.norm.running_mean',
                                 'enc_content.model.3.model.3.model.0.norm.running_var',
                                 )):
                    del state_dict[key]
        else:
            def __conversion_core(state_dict_base):
                state_dict = state_dict_base.copy()
                for key, value in state_dict_base.items():
                    if key.endswith(('enc.model.0.norm.running_mean',
                                     'enc.model.0.norm.running_var',
                                     'enc.model.1.norm.running_mean',
                                     'enc.model.1.norm.running_var',
                                     'enc.model.2.norm.running_mean',
                                     'enc.model.2.norm.running_var',
                                     'enc.model.3.model.0.model.1.norm.running_mean',
                                     'enc.model.3.model.0.model.1.norm.running_var',
                                     'enc.model.3.model.0.model.0.norm.running_mean',
                                     'enc.model.3.model.0.model.0.norm.running_var',
                                     'enc.model.3.model.1.model.1.norm.running_mean',
                                     'enc.model.3.model.1.model.1.norm.running_var',
                                     'enc.model.3.model.1.model.0.norm.running_mean',
                                     'enc.model.3.model.1.model.0.norm.running_var',
                                     'enc.model.3.model.2.model.1.norm.running_mean',
                                     'enc.model.3.model.2.model.1.norm.running_var',
                                     'enc.model.3.model.2.model.0.norm.running_mean',
                                     'enc.model.3.model.2.model.0.norm.running_var',
                                     'enc.model.3.model.3.model.1.norm.running_mean',
                                     'enc.model.3.model.3.model.1.norm.running_var',
                                     'enc.model.3.model.3.model.0.norm.running_mean',
                                     'enc.model.3.model.3.model.0.norm.running_var',

                                     'dec.model.0.model.0.model.1.norm.running_mean',
                                     'dec.model.0.model.0.model.1.norm.running_var',
                                     'dec.model.0.model.0.model.0.norm.running_mean',
                                     'dec.model.0.model.0.model.0.norm.running_var',
                                     'dec.model.0.model.1.model.1.norm.running_mean',
                                     'dec.model.0.model.1.model.1.norm.running_var',
                                     'dec.model.0.model.1.model.0.norm.running_mean',
                                     'dec.model.0.model.1.model.0.norm.running_var',
                                     'dec.model.0.model.2.model.1.norm.running_mean',
                                     'dec.model.0.model.2.model.1.norm.running_var',
                                     'dec.model.0.model.2.model.0.norm.running_mean',
                                     'dec.model.0.model.2.model.0.norm.running_var',
                                     'dec.model.0.model.3.model.1.norm.running_mean',
                                     'dec.model.0.model.3.model.1.norm.running_var',
                                     'dec.model.0.model.3.model.0.norm.running_mean',
                                     'dec.model.0.model.3.model.0.norm.running_var',
                                     )):
                        del state_dict[key]
        return state_dict

    state_dict = dict()
    state_dict['a'] = __conversion_core(state_dict_base['a'], trainer_name)
    state_dict['b'] = __conversion_core(state_dict_base['b'], trainer_name)
    return state_dict