yolo-tiling 0.0.17

Tile (slice) YOLO Dataset for Small Objects Detection and Instance Segmentation

YOLO Dataset tiling

This module can cut images and corresponding labels from a YOLO dataset into tiles of specified size and create a new dataset based on these tiles. It supports object detection, instance segmentation, and image classification. Credit for the original repository goes to slanj.

Installation

To install the package, use pip:

pip install yolo-tiling

Usage

from yolo_tiler import YoloTiler, TileConfig

src = "path/to/dataset"         # Source YOLO dataset directory
dst = "path/to/tiled_dataset"   # Output directory for tiled dataset

config = TileConfig(
    # Size of each tile (width, height). Can be:
    # - Single integer for square tiles: slice_wh=640
    # - Tuple for rectangular tiles: slice_wh=(640, 480)
    slice_wh=(640, 480),

    # Overlap between adjacent tiles. Can be:
    # - Single float (0-1) for uniform overlap percentage: overlap_wh=0.1
    # - Tuple of floats for different overlap in each dimension: overlap_wh=(0.1, 0.1)
    # - Single integer for pixel overlap: overlap_wh=64
    # - Tuple of integers for different pixel overlaps: overlap_wh=(64, 48)
    overlap_wh=(0.1, 0.1),

    # Input image file extension to process
    input_ext=".png",

    # Output image file extension to save (default: same as input_ext)
    output_ext=None,

    # Type of YOLO annotations to process:
    # - "object_detection": Standard YOLO format (class, x, y, width, height)
    # - "instance_segmentation": YOLO segmentation format (class, x1, y1, x2, y2, ...)
    # - "image_classification": YOLO classification format (class)
    annotation_type="instance_segmentation",

    # For segmentation only: Controls point density along polygon edges
    # Lower values = more points, higher quality but larger files
    densify_factor=0.01,

    # For segmentation only: Controls polygon smoothing
    # Lower values = more details preserved, higher values = smoother shapes
    smoothing_tolerance=0.99,

    # Dataset split ratios (must sum to 1.0)
    train_ratio=0.7,  # Proportion of data for training
    valid_ratio=0.2,  # Proportion of data for validation
    test_ratio=0.1,   # Proportion of data for testing

    # Optional margins to exclude from input images. Can be:
    # - Single float (0-1) for uniform margin percentage: margins=0.1
    # - Tuple of floats for different margins: margins=(0.1, 0.1, 0.1, 0.1)
    # - Single integer for pixel margins: margins=64
    # - Tuple of integers for different pixel margins: margins=(64, 64, 64, 64)
    margins=0.0,

    # Include negative samples (tiles without any instances)
    include_negative_samples=True

    # Include source data (copied over)
    copy_source_data=False
)

tiler = YoloTiler(
    source=src,
    target=dst,
    config=config,
    num_viz_samples=5,                      # Number of samples to visualize
    show_processing_status=True,            # Show the progress of the tiling process
    progress_callback=progress_callback     # Optional callback function to report progress (see below)
)

tiler.run()

@dataclass
class TileProgress:
    """Data class to track tiling progress"""
    current_set_name: str = ""
    current_image_name: str = ""
    current_image_idx: int = 0
    total_images: int = 0
    current_tile_idx: int = 0  
    total_tiles: int = 0  

Using TileProgress custom callback functions can be created. An example of an (optional) progress_callback function can be seen below:

from yolo_tiler import TilerProgress

def progress_callback(progress: TileProgress):
    # Determine whether to show tile or image progress
    if progress.total_tiles > 0:
        print(f"Processing {progress.current_image_name} in {progress.current_set_name} set: "
              f"Tile {progress.current_tile_idx}/{progress.total_tiles}")
    else:
        print(f"Processing {progress.current_image_name} in {progress.current_set_name} set: "
              f"Image {progress.current_image_idx}/{progress.total_images}")

Notes

• The tiler requires a YOLO dataset structure within the source directory (see below).
• If only a train folder exists, the train / valid / test ratios will be used to split the tiled train folder.
• If there already exists train / valid / test folders in the source directory, the ratios are ignored.
• Tiles are named as basename_top-left_bottom-right_width_height.ext.
• copy_source_data will make copy the original YOLO dataset to the output folder (for multiscale).
• Pay attention to the differences between the valid and val folder for different tasks.

Object Detection and Instance Segmentation

dataset/
├── train/
│   ├── images/
│   └── labels/
├── valid/  # <--- "valid", not "val"
│   ├── images/
│   └── labels/
├── test/
│   ├── images/
│   └── labels/
└── data.yaml  # Optional

Image Classification

dataset/
├── train/
│   ├── class_1/
│   └── class_2/
├── val/    # <--- "val", not "valid"
│   ├── class_1/
│   └── class_2/
├── test/
    ├── class_1/
    └── class_2/

Test Data

python tests/test_yolo_tiler.py

Command Line Usage

In addition to using the tiler within a script, it can also use the command line interface to run the tiling process. Here are the instructions:

yolo_tiler --source --target [--slice_wh SLICE_WH SLICE_WH] [--overlap_wh OVERLAP_WH OVERLAP_WH] [--input_ext INPUT_EXT] [--output_ext OUTPUT_EXT] [--annotation_type ANNOTATION_TYPE] [--densify_factor DENSIFY_FACTOR] [--smoothing_tolerance SMOOTHING_TOLERANCE] [--train_ratio TRAIN_RATIO] [--valid_ratio VALID_RATIO] [--test_ratio TEST_RATIO] [--margins MARGINS] [--include_negative_samples INCLUDE_NEGATIVE_SAMPLES]

Example Commands

1. Basic usage with default parameters:

yolo_tiler --source tests/detection --target tests/detection_tiled

2. Custom slice size and overlap:

yolo_tiler --source tests/detection --target tests/detection_tiled --slice_wh 640 480 --overlap_wh 0.1 0.1

3. Custom annotation type and image extension:

yolo_tiler --source tests/segmentation --target tests/segmentation_tiled --annotation_type instance_segmentation --input_ext .jpg --output_ext .png

Memory Efficiency

The tile_image method now uses rasterio's Window to read and process image tiles directly from the disk, instead of loading the entire image into memory. This makes the tiling process more memory efficient, especially for large images.

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Disclaimer

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License

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