# Copyright (c) 2025 GeoBenchV2. All rights reserved.
# Licensed under the Apache License 2.0.
"""GeoBench NZCattle DataModule."""
import os
from collections.abc import Callable, Sequence
from typing import Any
import matplotlib.pyplot as plt
import numpy as np
import pandas as pd
import tacoreader
import torch
import torch.nn as nn
from einops import rearrange
from torchgeo.datasets.utils import percentile_normalization
from geobench_v2.datasets import GeoBenchNZCattle
from .base import GeoBenchObjectDetectionDataModule
def nzcattle_collate_fn(batch: Sequence[dict[str, Any]]) -> dict[str, Any]:
"""Collate function for nzCattle dataset.
Args:
batch: A list of dictionaries containing the data for each sample
Returns:
A dictionary containing the collated data
"""
# collate images
images = [sample["image"] for sample in batch]
images = torch.stack(images, dim=0)
# collate boxes into list of boxes
boxes = [sample["bbox_xyxy"] for sample in batch]
label = [sample["label"] for sample in batch]
return {"image": images, "bbox_xyxy": boxes, "label": label}
[docs]
class GeoBenchNZCattleDataModule(GeoBenchObjectDetectionDataModule):
"""GeoBench nzCattle Data Module."""
[docs]
def __init__(
self,
img_size: int = 512,
band_order: Sequence[float | str] = GeoBenchNZCattle.band_default_order,
batch_size: int = 32,
eval_batch_size: int = 64,
num_workers: int = 0,
collate_fn: Callable | None = nzcattle_collate_fn,
train_augmentations: nn.Module | None = None,
eval_augmentations: nn.Module | None = None,
pin_memory: bool = False,
**kwargs: Any,
) -> None:
"""Initialize GeoBench nzCattle dataset module.
Args:
img_size: Image size
band_order: The order of bands to return, defaults to ['red', 'green', 'blue'], if one would
specify ['red', 'green', 'blue', 'blue'], the dataset would return images with 4 channels
in that order. This is useful for models that expect a certain band order, or
test the impact of band order on model performance.
batch_size: Batch size during
eval_batch_size: Evaluation batch size
num_workers: Number of workers
collate_fn: Collate function
train_augmentations: Transforms/Augmentations to apply during training, they will be applied
at the sample level and should include normalization. See :meth:`define_augmentations`
for the default transformation.
eval_augmentations: Transforms/Augmentations to apply during evaluation, they will be applied
at the sample level and should include normalization. See :meth:`define_augmentations`
for the default transformation.
pin_memory: Pin memory
**kwargs: Additional keyword arguments for :class:`geobench_v2.datasets.nzcattle.GeoBenchNZCattle`
"""
super().__init__(
dataset_class=GeoBenchNZCattle,
img_size=img_size,
band_order=band_order,
batch_size=batch_size,
eval_batch_size=eval_batch_size,
num_workers=num_workers,
collate_fn=collate_fn,
train_augmentations=train_augmentations,
eval_augmentations=eval_augmentations,
pin_memory=pin_memory,
**kwargs,
)
[docs]
def visualize_batch(
self, batch: dict[str, Any] | None = None, split: str = "train"
) -> tuple[Any, dict[str, Any]]:
"""Visualize a batch of data.
Args:
batch: A batch of data (optional)
split: One of 'train', 'validation', 'test'
Returns:
The matplotlib figure and the batch of data
"""
if split == "train":
batch = next(iter(self.train_dataloader()))
elif split == "validation":
batch = next(iter(self.val_dataloader()))
else:
batch = next(iter(self.test_dataloader()))
if hasattr(self.data_normalizer, "unnormalize"):
batch = self.data_normalizer.unnormalize(batch)
images = batch["image"]
boxes_batch = batch["bbox_xyxy"]
labels_batch = batch["label"]
batch_size = images.shape[0]
n_samples = min(8, batch_size)
indices = torch.randperm(batch_size)[:n_samples]
images = images[indices]
boxes_batch = [boxes_batch[i] for i in indices]
labels_batch = [labels_batch[i] for i in indices]
plot_bands = self.dataset_band_config.plot_bands
rgb_indices = [
self.band_order.index(band)
for band in plot_bands
if band in self.band_order
]
images = images[:, rgb_indices, :, :]
fig, axes = plt.subplots(
n_samples,
2,
figsize=(14, 5 * n_samples),
gridspec_kw={"width_ratios": [3, 1]},
)
if n_samples == 1:
axes = np.array([axes])
num_classes = len(self.class_names)
colors = plt.cm.tab20(np.linspace(0, 1, num_classes))
legend_elements = []
for i, name in enumerate(self.class_names):
legend_elements.append(
plt.Line2D(
[0],
[0],
marker="s",
color="w",
markerfacecolor=colors[i],
markersize=10,
label=name,
)
)
for i in range(n_samples):
ax_img = axes[i, 0]
img = rearrange(images[i], "c h w -> h w c").cpu().numpy()
img = percentile_normalization(img, lower=2, upper=98)
ax_img.imshow(img)
boxes = boxes_batch[i]
labels = labels_batch[i]
class_counts = {}
for label in labels:
if isinstance(label, torch.Tensor):
label = label.item()
class_name = self.class_names[int(label)]
class_counts[class_name] = class_counts.get(class_name, 0) + 1
for box, label in zip(boxes, labels):
if isinstance(box, torch.Tensor):
box = box.cpu().numpy()
if isinstance(label, torch.Tensor):
label = label.item()
x1, y1, x2, y2 = box
color = colors[int(label)]
rect = plt.Rectangle(
(x1, y1),
x2 - x1,
y2 - y1,
linewidth=2,
edgecolor=color,
facecolor="none",
)
ax_img.add_patch(rect)
ax_img.set_title(f"Sample {i + 1}" if i == 0 else "")
ax_img.set_xticks([])
ax_img.set_yticks([])
ax_stats = axes[i, 1]
ax_stats.axis("off")
if class_counts:
sorted_items = sorted(
class_counts.items(), key=lambda x: x[1], reverse=True
)
start_y_pos = 0.9
y_pos = start_y_pos
total = sum(class_counts.values())
ax_stats.text(
0.1,
y_pos,
f"Total: {total}",
va="top",
fontsize=15,
fontweight="bold",
)
y_pos -= 0.05
for name, count in sorted_items:
y_pos -= 0.04
class_idx = self.class_names.index(name)
color = colors[class_idx]
square = plt.Rectangle(
(0.05, y_pos), 0.03, 0.03, facecolor=color, edgecolor="black"
)
ax_stats.add_patch(square)
ax_stats.text(
0.1, y_pos, f" {name}: {count}", va="center", fontsize=15
)
counts_box = plt.Rectangle(
(0.01, y_pos - 0.02),
0.9,
(start_y_pos + 0.02) - (y_pos - 0.02),
fill=False,
edgecolor="gray",
linestyle="--",
transform=ax_stats.transAxes,
)
ax_stats.add_patch(counts_box)
else:
ax_stats.text(0.1, 0.5, "No objects detected", va="center")
plt.tight_layout()
return fig, batch
[docs]
def visualize_geolocation_distribution(self) -> None:
"""Visualize the geolocation distribution of the dataset."""
pass