import numpy as np import os.path from data.base_dataset import BaseDataset, get_transform from data.image_folder import make_dataset from PIL import Image import random import util.util as util class SingleImageDataset(BaseDataset): """ This dataset class can load unaligned/unpaired datasets. It requires two directories to host training images from domain A '/path/to/data/trainA' and from domain B '/path/to/data/trainB' respectively. You can train the model with the dataset flag '--dataroot /path/to/data'. Similarly, you need to prepare two directories: '/path/to/data/testA' and '/path/to/data/testB' during test time. """ def __init__(self, opt): """Initialize this dataset class. Parameters: opt (Option class) -- stores all the experiment flags; needs to be a subclass of BaseOptions """ BaseDataset.__init__(self, opt) self.dir_A = os.path.join(opt.dataroot, 'trainA') # create a path '/path/to/data/trainA' self.dir_B = os.path.join(opt.dataroot, 'trainB') # create a path '/path/to/data/trainB' if os.path.exists(self.dir_A) and os.path.exists(self.dir_B): self.A_paths = sorted(make_dataset(self.dir_A, opt.max_dataset_size)) # load images from '/path/to/data/trainA' self.B_paths = sorted(make_dataset(self.dir_B, opt.max_dataset_size)) # load images from '/path/to/data/trainB' self.A_size = len(self.A_paths) # get the size of dataset A self.B_size = len(self.B_paths) # get the size of dataset B assert len(self.A_paths) == 1 and len(self.B_paths) == 1,\ "SingleImageDataset class should be used with one image in each domain" A_img = Image.open(self.A_paths[0]).convert('RGB') B_img = Image.open(self.B_paths[0]).convert('RGB') print("Image sizes %s and %s" % (str(A_img.size), str(B_img.size))) self.A_img = A_img self.B_img = B_img # In single-image translation, we augment the data loader by applying # random scaling. Still, we design the data loader such that the # amount of scaling is the same within a minibatch. To do this, # we precompute the random scaling values, and repeat them by |batch_size|. A_zoom = 1 / self.opt.random_scale_max zoom_levels_A = np.random.uniform(A_zoom, 1.0, size=(len(self) // opt.batch_size + 1, 1, 2)) self.zoom_levels_A = np.reshape(np.tile(zoom_levels_A, (1, opt.batch_size, 1)), [-1, 2]) B_zoom = 1 / self.opt.random_scale_max zoom_levels_B = np.random.uniform(B_zoom, 1.0, size=(len(self) // opt.batch_size + 1, 1, 2)) self.zoom_levels_B = np.reshape(np.tile(zoom_levels_B, (1, opt.batch_size, 1)), [-1, 2]) # While the crop locations are randomized, the negative samples should # not come from the same location. To do this, we precompute the # crop locations with no repetition. self.patch_indices_A = list(range(len(self))) random.shuffle(self.patch_indices_A) self.patch_indices_B = list(range(len(self))) random.shuffle(self.patch_indices_B) def __getitem__(self, index): """Return a data point and its metadata information. Parameters: index (int) -- a random integer for data indexing Returns a dictionary that contains A, B, A_paths and B_paths A (tensor) -- an image in the input domain B (tensor) -- its corresponding image in the target domain A_paths (str) -- image paths B_paths (str) -- image paths """ A_path = self.A_paths[0] B_path = self.B_paths[0] A_img = self.A_img B_img = self.B_img # apply image transformation if self.opt.phase == "train": param = {'scale_factor': self.zoom_levels_A[index], 'patch_index': self.patch_indices_A[index], 'flip': random.random() > 0.5} transform_A = get_transform(self.opt, params=param, method=Image.BILINEAR) A = transform_A(A_img) param = {'scale_factor': self.zoom_levels_B[index], 'patch_index': self.patch_indices_B[index], 'flip': random.random() > 0.5} transform_B = get_transform(self.opt, params=param, method=Image.BILINEAR) B = transform_B(B_img) else: transform = get_transform(self.opt, method=Image.BILINEAR) A = transform(A_img) B = transform(B_img) return {'A': A, 'B': B, 'A_paths': A_path, 'B_paths': B_path} def __len__(self): """ Let's pretend the single image contains 100,000 crops for convenience. """ return 100000