Datasets:

TrainingDataPro
/

generated-usa-passeports-dataset

Tasks:

Image-to-Image

Languages:

English

License:

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generated-usa-passeports-dataset / generated-usa-passeports-dataset.py

Vadzim Kashko

fix: image representation as np.ndarray

3cb14b5 11 months ago

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	import datasets
	import PIL.Image
	import PIL.ImageOps
	import numpy as np

	_CITATION = """\
	@InProceedings{huggingface:dataset,
	title = {generated-usa-passeports-dataset},
	author = {TrainingDataPro},
	year = {2023}
	}
	"""

	_DESCRIPTION = """\
	Data generation in machine learning involves creating or manipulating data
	to train and evaluate machine learning models. The purpose of data generation
	is to provide diverse and representative examples that cover a wide range of
	scenarios, ensuring the model's robustness and generalization.
	Data augmentation techniques involve applying various transformations to
	existing data samples to create new ones. These transformations include:
	random rotations, translations, scaling, flips, and more. Augmentation helps
	in increasing the dataset size, introducing natural variations, and improving
	model performance by making it more invariant to specific transformations.
	The dataset contains GENERATED USA passports, which are replicas of
	official passports but with randomly generated details, such as name, date of
	birth etc. The primary intention of generating these fake passports is to
	demonstrate the structure and content of a typical passport document and to
	train the neural network to identify this type of document.
	Generated passports can assist in conducting research without accessing or
	compromising real user data that is often sensitive and subject to privacy
	regulations. Synthetic data generation allows researchers to develop and
	refine models using simulated passport data without risking privacy leaks.
	"""
	_NAME = 'generated-usa-passeports-dataset'

	_HOMEPAGE = f"https://huggingface.co/datasets/TrainingDataPro/{_NAME}"

	_LICENSE = "cc-by-nc-nd-4.0"

	_DATA = f"https://huggingface.co/datasets/TrainingDataPro/{_NAME}/resolve/main/data/"


	def exif_transpose(img):
	if not img:
	return img

	exif_orientation_tag = 274

	# Check for EXIF data (only present on some files)
	if hasattr(img, "_getexif") and isinstance(
	img._getexif(), dict) and exif_orientation_tag in img._getexif():
	exif_data = img._getexif()
	orientation = exif_data[exif_orientation_tag]

	# Handle EXIF Orientation
	if orientation == 1:
	# Normal image - nothing to do!
	pass
	elif orientation == 2:
	# Mirrored left to right
	img = img.transpose(PIL.Image.FLIP_LEFT_RIGHT)
	elif orientation == 3:
	# Rotated 180 degrees
	img = img.rotate(180)
	elif orientation == 4:
	# Mirrored top to bottom
	img = img.rotate(180).transpose(PIL.Image.FLIP_LEFT_RIGHT)
	elif orientation == 5:
	# Mirrored along top-left diagonal
	img = img.rotate(-90,
	expand=True).transpose(PIL.Image.FLIP_LEFT_RIGHT)
	elif orientation == 6:
	# Rotated 90 degrees
	img = img.rotate(-90, expand=True)
	elif orientation == 7:
	# Mirrored along top-right diagonal
	img = img.rotate(90,
	expand=True).transpose(PIL.Image.FLIP_LEFT_RIGHT)
	elif orientation == 8:
	# Rotated 270 degrees
	img = img.rotate(90, expand=True)

	return img


	def load_image_file(file, mode='RGB'):
	# Load the image with PIL
	img = PIL.Image.open(file)

	if hasattr(PIL.ImageOps, 'exif_transpose'):
	# Very recent versions of PIL can do exit transpose internally
	img = PIL.ImageOps.exif_transpose(img)
	else:
	# Otherwise, do the exif transpose ourselves
	img = exif_transpose(img)

	img = img.convert(mode)

	return np.array(img)


	class GeneratedUsaPasseportsDataset(datasets.GeneratorBasedBuilder):

	def _info(self):
	return datasets.DatasetInfo(
	description=_DESCRIPTION,
	features=datasets.Features({
	'original': datasets.Image(),
	'us_pass_augmentated_1': datasets.Image(),
	'us_pass_augmentated_2': datasets.Image(),
	'us_pass_augmentated_3': datasets.Image()
	}),
	supervised_keys=None,
	homepage=_HOMEPAGE,
	citation=_CITATION,
	license=_LICENSE)

	def _split_generators(self, dl_manager):
	original = dl_manager.download_and_extract(f"{_DATA}original.zip")
	augmentation = dl_manager.download_and_extract(
	f"{_DATA}augmentation.zip")
	annotations = dl_manager.download(f"{_DATA}{_NAME}.csv")
	original = dl_manager.iter_files(original)
	augmentation = dl_manager.iter_files(augmentation)
	return [
	datasets.SplitGenerator(name=datasets.Split.TRAIN,
	gen_kwargs={
	"original": original,
	'augmentation': augmentation,
	'annotations': annotations
	}),
	]

	def _generate_examples(self, original, augmentation, annotations):
	original = list(original)
	augmentation = list(augmentation)
	augmentation = [
	augmentation[i:i + 3] for i in range(0, len(augmentation), 3)
	]

	for idx, (org, aug) in enumerate(zip(original, augmentation)):
	yield idx, {
	'original': load_image_file(org),
	'us_pass_augmentated_1': load_image_file(aug[0]),
	'us_pass_augmentated_2': load_image_file(aug[1]),
	'us_pass_augmentated_3': load_image_file(aug[2])
	}