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

_CITATION = """\
@InProceedings{huggingface:dataset,
title = {facial_keypoint_detection},
author = {TrainingDataPro},
year = {2023}
}
"""

_DESCRIPTION = """\
The dataset is designed for computer vision and machine learning tasks
involving the identification and analysis of key points on a human face.
It consists of images of human faces, each accompanied by key point
annotations in XML format.
"""
_NAME = 'facial_keypoint_detection'

_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)
    img.thumbnail((1000, 1000), PIL.Image.Resampling.LANCZOS)

    return img


class FacialKeypointDetection(datasets.GeneratorBasedBuilder):

    def _info(self):
        return datasets.DatasetInfo(description=_DESCRIPTION,
                                    features=datasets.Features({
                                        'image_id': datasets.Value('uint32'),
                                        'image': datasets.Image(),
                                        'mask': datasets.Image(),
                                        'key_points': datasets.Value('string')
                                    }),
                                    supervised_keys=None,
                                    homepage=_HOMEPAGE,
                                    citation=_CITATION,
                                    license=_LICENSE)

    def _split_generators(self, dl_manager):
        # images = dl_manager.download_and_extract(f"{_DATA}images.zip")
        # masks = dl_manager.download_and_extract(f"{_DATA}masks.zip")
        images = dl_manager.download(f"{_DATA}images.tar.gz")
        masks = dl_manager.download(f"{_DATA}masks.tar.gz")
        annotations = dl_manager.download(f"{_DATA}{_NAME}.csv")
        # images = dl_manager.iter_files(images)
        # masks = dl_manager.iter_files(masks)
        images = dl_manager.iter_archive(images)
        masks = dl_manager.iter_archive(masks)

        return [
            datasets.SplitGenerator(name=datasets.Split.TRAIN,
                                    gen_kwargs={
                                        "images": images,
                                        "masks": masks,
                                        'annotations': annotations
                                    }),
        ]

    def _generate_examples(self, images, masks, annotations):
        annotations_df = pd.read_csv(annotations, sep=',')
        for idx, ((image_path, image),
                  (mask_path, mask)) in enumerate(zip(images, masks)):
            yield idx, {
                'image_id': annotations_df['image_id'].iloc[idx],
                "image": {
                    "path": image_path,
                    "bytes": image.read()
                },
                "mask": {
                    "path": mask_path,
                    "bytes": mask.read()
                },
                'key_points': annotations_df['key_points'].iloc[idx]
            }
        # images_data = pd.DataFrame(
        #     columns=['image_name', 'image_path', 'mask_path'])
        # for idx, ((image_path, image),
        #           (mask_path, mask)) in enumerate(zip(images, masks)):
        #     images_data.loc[idx] = {
        #         'image_name': image_path.split('/')[-1],
        #         'image_path': image_path,
        #         'mask_path': mask_path
        #     }

        # annotations_df = pd.merge(annotations_df,
        #                           images_data,
        #                           how='left',
        #                           on=['image_name'])

        # annotations_df[['image_path', 'mask_path'
        #                ]] = annotations_df[['image_path',
        #                                     'mask_path']].astype('string')

        # for row in annotations_df.sort_values(['image_name'
        #                                       ]).itertuples(index=False):
        #     yield idx, {
        #         'image_id': row[0],
        #         'image': row[3],
        #         'mask': row[4],
        #         'key_points': row[2]
        #     }