Source code for torchgeo.datasets.bigearthnet
# Copyright (c) Microsoft Corporation. All rights reserved.
# Licensed under the MIT License.
"""BigEarthNet dataset."""
import glob
import json
import os
from typing import Callable, Dict, List, Optional
import matplotlib.pyplot as plt
import numpy as np
import rasterio
import torch
from rasterio.enums import Resampling
from torch import Tensor
from .geo import VisionDataset
from .utils import download_url, extract_archive, sort_sentinel2_bands
class BigEarthNet(VisionDataset):
"""BigEarthNet dataset.
The `BigEarthNet <http://bigearth.net/>`_
dataset is a dataset for multilabel remote sensing image scene classification.
Dataset features:
* 590,326 patches from 125 Sentinel-1 and Sentinel-2 tiles
* Imagery from tiles in Europe between Jun 2017 - May 2018
* 12 spectral bands with 10-60 m per pixel resolution (base 120x120 px)
* 2 synthetic aperture radar bands (120x120 px)
* 43 or 19 scene classes from the 2018 CORINE Land Cover database (CLC 2018)
Dataset format:
* images are composed of multiple single channel geotiffs
* labels are multiclass, stored in a single json file per image
* mapping of Sentinel-1 to Sentinel-2 patches are within Sentinel-1 json files
* Sentinel-1 bands: (VV, VH)
* Sentinel-2 bands: (B01, B02, B03, B04, B05, B06, B07, B08, B8A, B09, B11, B12)
* All bands: (VV, VH, B01, B02, B03, B04, B05, B06, B07, B08, B8A, B09, B11, B12)
* Sentinel-2 bands are of different spatial resolutions and upsampled to 10m
Dataset classes (43):
0. Agro-forestry areas
1. Airports
2. Annual crops associated with permanent crops
3. Bare rock
4. Beaches, dunes, sands
5. Broad-leaved forest
6. Burnt areas
7. Coastal lagoons
8. Complex cultivation patterns
9. Coniferous forest
10. Construction sites
11. Continuous urban fabric
12. Discontinuous urban fabric
13. Dump sites
14. Estuaries
15. Fruit trees and berry plantations
16. Green urban areas
17. Industrial or commercial units
18. Inland marshes
19. Intertidal flats
20. Land principally occupied by agriculture, with significant
areas of natural vegetation
21. Mineral extraction sites
22. Mixed forest
23. Moors and heathland
24. Natural grassland
25. Non-irrigated arable land
26. Olive groves
27. Pastures
28. Peatbogs
29. Permanently irrigated land
30. Port areas
31. Rice fields
32. Road and rail networks and associated land
33. Salines
34. Salt marshes
35. Sclerophyllous vegetation
36. Sea and ocean
37. Sparsely vegetated areas
38. Sport and leisure facilities
39. Transitional woodland/shrub
40. Vineyards
41. Water bodies
42. Water courses
Dataset classes (19):
0. Urban fabric
1. Industrial or commercial units
2. Arable land
3. Permanent crops
4. Pastures
5. Complex cultivation patterns
6. Land principally occupied by agriculture, with significant
areas of natural vegetation
7. Agro-forestry areas
8. Broad-leaved forest
9. Coniferous forest
10. Mixed forest
11. Natural grassland and sparsely vegetated areas
12. Moors, heathland and sclerophyllous vegetation
13. Transitional woodland, shrub
14. Beaches, dunes, sands
15. Inland wetlands
16. Coastal wetlands
17. Inland waters
18. Marine waters
If you use this dataset in your research, please cite the following paper:
* https://doi.org/10.1109/IGARSS.2019.8900532
"""
class_sets = {
19: [
"Urban fabric",
"Industrial or commercial units",
"Arable land",
"Permanent crops",
"Pastures",
"Complex cultivation patterns",
"Land principally occupied by agriculture, with significant areas of"
" natural vegetation",
"Agro-forestry areas",
"Broad-leaved forest",
"Coniferous forest",
"Mixed forest",
"Natural grassland and sparsely vegetated areas",
"Moors, heathland and sclerophyllous vegetation",
"Transitional woodland, shrub",
"Beaches, dunes, sands",
"Inland wetlands",
"Coastal wetlands",
"Inland waters",
"Marine waters",
],
43: [
"Agro-forestry areas",
"Airports",
"Annual crops associated with permanent crops",
"Bare rock",
"Beaches, dunes, sands",
"Broad-leaved forest",
"Burnt areas",
"Coastal lagoons",
"Complex cultivation patterns",
"Coniferous forest",
"Construction sites",
"Continuous urban fabric",
"Discontinuous urban fabric",
"Dump sites",
"Estuaries",
"Fruit trees and berry plantations",
"Green urban areas",
"Industrial or commercial units",
"Inland marshes",
"Intertidal flats",
"Land principally occupied by agriculture, with significant areas of"
" natural vegetation",
"Mineral extraction sites",
"Mixed forest",
"Moors and heathland",
"Natural grassland",
"Non-irrigated arable land",
"Olive groves",
"Pastures",
"Peatbogs",
"Permanently irrigated land",
"Port areas",
"Rice fields",
"Road and rail networks and associated land",
"Salines",
"Salt marshes",
"Sclerophyllous vegetation",
"Sea and ocean",
"Sparsely vegetated areas",
"Sport and leisure facilities",
"Transitional woodland/shrub",
"Vineyards",
"Water bodies",
"Water courses",
],
}
label_converter = {
0: 0,
1: 0,
2: 1,
11: 2,
12: 2,
13: 2,
14: 3,
15: 3,
16: 3,
18: 3,
17: 4,
19: 5,
20: 6,
21: 7,
22: 8,
23: 9,
24: 10,
25: 11,
31: 11,
26: 12,
27: 12,
28: 13,
29: 14,
33: 15,
34: 15,
35: 16,
36: 16,
38: 17,
39: 17,
40: 18,
41: 18,
42: 18,
}
splits_metadata = {
"train": {
"url": "https://git.tu-berlin.de/rsim/BigEarthNet-MM_19-classes_models/-/raw/master/splits/train.csv?inline=false", # noqa: E501
"filename": "bigearthnet-train.csv",
"md5": "623e501b38ab7b12fe44f0083c00986d",
},
"val": {
"url": "https://git.tu-berlin.de/rsim/BigEarthNet-MM_19-classes_models/-/raw/master/splits/val.csv?inline=false", # noqa: E501
"filename": "bigearthnet-val.csv",
"md5": "22efe8ed9cbd71fa10742ff7df2b7978",
},
"test": {
"url": "https://git.tu-berlin.de/rsim/BigEarthNet-MM_19-classes_models/-/raw/master/splits/test.csv?inline=false", # noqa: E501
"filename": "bigearthnet-test.csv",
"md5": "697fb90677e30571b9ac7699b7e5b432",
},
}
metadata = {
"s1": {
"url": "http://bigearth.net/downloads/BigEarthNet-S1-v1.0.tar.gz",
"md5": "5a64e9ce38deb036a435a7b59494924c",
"filename": "BigEarthNet-S1-v1.0.tar.gz",
"directory": "BigEarthNet-S1-v1.0",
},
"s2": {
"url": "http://bigearth.net/downloads/BigEarthNet-S2-v1.0.tar.gz",
"md5": "5a64e9ce38deb036a435a7b59494924c",
"filename": "BigEarthNet-S2-v1.0.tar.gz",
"directory": "BigEarthNet-v1.0",
},
}
image_size = (120, 120)
[docs] def __init__(
self,
root: str = "data",
split: str = "train",
bands: str = "all",
num_classes: int = 19,
transforms: Optional[Callable[[Dict[str, Tensor]], Dict[str, Tensor]]] = None,
download: bool = False,
checksum: bool = False,
) -> None:
"""Initialize a new BigEarthNet dataset instance.
Args:
root: root directory where dataset can be found
split: train/val/test split to load
bands: load Sentinel-1 bands, Sentinel-2, or both. one of {s1, s2, all}
num_classes: number of classes to load in target. one of {19, 43}
transforms: a function/transform that takes input sample and its target as
entry and returns a transformed version
download: if True, download dataset and store it in the root directory
checksum: if True, check the MD5 of the downloaded files (may be slow)
"""
assert split in self.splits_metadata
assert bands in ["s1", "s2", "all"]
assert num_classes in [43, 19]
self.root = root
self.split = split
self.bands = bands
self.num_classes = num_classes
self.transforms = transforms
self.download = download
self.checksum = checksum
self.class2idx = {c: i for i, c in enumerate(self.class_sets[43])}
self._verify()
self.folders = self._load_folders()
[docs] def __getitem__(self, index: int) -> Dict[str, Tensor]:
"""Return an index within the dataset.
Args:
index: index to return
Returns:
data and label at that index
"""
image = self._load_image(index)
label = self._load_target(index)
sample: Dict[str, Tensor] = {"image": image, "label": label}
if self.transforms is not None:
sample = self.transforms(sample)
return sample
[docs] def __len__(self) -> int:
"""Return the number of data points in the dataset.
Returns:
length of the dataset
"""
return len(self.folders)
def _load_folders(self) -> List[Dict[str, str]]:
"""Load folder paths.
Returns:
list of dicts of s1 and s2 folder paths
"""
filename = self.splits_metadata[self.split]["filename"]
dir_s1 = self.metadata["s1"]["directory"]
dir_s2 = self.metadata["s2"]["directory"]
with open(os.path.join(self.root, filename)) as f:
lines = f.read().strip().splitlines()
pairs = [line.split(",") for line in lines]
folders = [
{
"s1": os.path.join(self.root, dir_s1, pair[1]),
"s2": os.path.join(self.root, dir_s2, pair[0]),
}
for pair in pairs
]
return folders
def _load_paths(self, index: int) -> List[str]:
"""Load paths to band files.
Args:
index: index to return
Returns:
list of file paths
"""
if self.bands == "all":
folder_s1 = self.folders[index]["s1"]
folder_s2 = self.folders[index]["s2"]
paths_s1 = glob.glob(os.path.join(folder_s1, "*.tif"))
paths_s2 = glob.glob(os.path.join(folder_s2, "*.tif"))
paths_s1 = sorted(paths_s1)
paths_s2 = sorted(paths_s2, key=sort_sentinel2_bands)
paths = paths_s1 + paths_s2
elif self.bands == "s1":
folder = self.folders[index]["s1"]
paths = glob.glob(os.path.join(folder, "*.tif"))
paths = sorted(paths)
else:
folder = self.folders[index]["s2"]
paths = glob.glob(os.path.join(folder, "*.tif"))
paths = sorted(paths, key=sort_sentinel2_bands)
return paths
def _load_image(self, index: int) -> Tensor:
"""Load a single image.
Args:
index: index to return
Returns:
the raster image or target
"""
paths = self._load_paths(index)
images = []
for path in paths:
# Bands are of different spatial resolutions
# Resample to (120, 120)
with rasterio.open(path) as dataset:
array = dataset.read(
indexes=1,
out_shape=self.image_size,
out_dtype="int32",
resampling=Resampling.bilinear,
)
images.append(array)
arrays: "np.typing.NDArray[np.int_]" = np.stack(images, axis=0)
tensor = torch.from_numpy(arrays)
return tensor
def _load_target(self, index: int) -> Tensor:
"""Load the target mask for a single image.
Args:
index: index to return
Returns:
the target label
"""
if self.bands == "s2":
folder = self.folders[index]["s2"]
else:
folder = self.folders[index]["s1"]
path = glob.glob(os.path.join(folder, "*.json"))[0]
with open(path, "r") as f:
labels = json.load(f)["labels"]
# labels -> indices
indices = [self.class2idx[label] for label in labels]
# Map 43 to 19 class labels
if self.num_classes == 19:
indices_optional = [self.label_converter.get(idx) for idx in indices]
indices = [idx for idx in indices_optional if idx is not None]
target = torch.zeros(self.num_classes, dtype=torch.long)
target[indices] = 1
return target
def _verify(self) -> None:
"""Verify the integrity of the dataset.
Raises:
RuntimeError: if ``download=False`` but dataset is missing or checksum fails
"""
keys = ["s1", "s2"] if self.bands == "all" else [self.bands]
urls = [self.metadata[k]["url"] for k in keys]
md5s = [self.metadata[k]["md5"] for k in keys]
filenames = [self.metadata[k]["filename"] for k in keys]
directories = [self.metadata[k]["directory"] for k in keys]
urls.extend([self.splits_metadata[k]["url"] for k in self.splits_metadata])
md5s.extend([self.splits_metadata[k]["md5"] for k in self.splits_metadata])
filenames_splits = [
self.splits_metadata[k]["filename"] for k in self.splits_metadata
]
filenames.extend(filenames_splits)
# Check if the split file already exist
exists = []
for filename in filenames_splits:
exists.append(os.path.exists(os.path.join(self.root, filename)))
# Check if the files already exist
for directory in directories:
exists.append(os.path.exists(os.path.join(self.root, directory)))
if all(exists):
return
# Check if zip file already exists (if so then extract)
exists = []
for filename in filenames:
filepath = os.path.join(self.root, filename)
if os.path.exists(filepath):
exists.append(True)
self._extract(filepath)
else:
exists.append(False)
if all(exists):
return
# Check if the user requested to download the dataset
if not self.download:
raise RuntimeError(
"Dataset not found in `root` directory and `download=False`, "
"either specify a different `root` directory or use `download=True` "
"to automaticaly download the dataset."
)
# Download and extract the dataset
for url, filename, md5 in zip(urls, filenames, md5s):
self._download(url, filename, md5)
filepath = os.path.join(self.root, filename)
self._extract(filepath)
def _download(self, url: str, filename: str, md5: str) -> None:
"""Download the dataset.
Args:
url: url to download file
filename: output filename to write downloaded file
md5: md5 of downloaded file
"""
if not os.path.exists(filename):
download_url(
url, self.root, filename=filename, md5=md5 if self.checksum else None
)
def _extract(self, filepath: str) -> None:
"""Extract the dataset.
Args:
filepath: path to file to be extracted
"""
if not filepath.endswith(".csv"):
extract_archive(filepath)
def _onehot_labels_to_names(
self, label_mask: "np.typing.NDArray[np.bool_]"
) -> List[str]:
"""Gets a list of class names given a label mask.
Args:
label_mask: a boolean mask corresponding to a set of labels or predictions
Returns
a list of class names corresponding to the input mask
"""
labels = []
for i, mask in enumerate(label_mask):
if mask:
labels.append(self.class_sets[self.num_classes][i])
return labels
[docs] def plot(
self,
sample: Dict[str, Tensor],
show_titles: bool = True,
suptitle: Optional[str] = None,
) -> plt.Figure:
"""Plot a sample from the dataset.
Args:
sample: a sample returned by :meth:`__getitem__`
show_titles: flag indicating whether to show titles above each panel
suptitle: optional string to use as a suptitle
Returns:
a matplotlib Figure with the rendered sample
Raises:
ValueError: if ``self.bands`` is "s1"
.. versionadded:: 0.2
"""
if self.bands == "s2":
image = np.rollaxis(sample["image"][[3, 2, 1]].numpy(), 0, 3)
image = np.clip(image / 2000, 0, 1)
elif self.bands == "all":
image = np.rollaxis(sample["image"][[5, 4, 3]].numpy(), 0, 3)
image = np.clip(image / 2000, 0, 1)
elif self.bands == "s1":
image = sample["image"][0].numpy()
label_mask = sample["label"].numpy().astype(np.bool_)
labels = self._onehot_labels_to_names(label_mask)
showing_predictions = "prediction" in sample
if showing_predictions:
prediction_mask = sample["prediction"].numpy().astype(np.bool_)
predictions = self._onehot_labels_to_names(prediction_mask)
fig, ax = plt.subplots(figsize=(4, 4))
ax.imshow(image)
ax.axis("off")
if show_titles:
title = f"Labels: {', '.join(labels)}"
if showing_predictions:
title += f"\nPredictions: {', '.join(predictions)}"
ax.set_title(title)
if suptitle is not None:
plt.suptitle(suptitle)
return fig
