images-to-zarr 0.3.2

Tiny Python module to bulk-convert large amounts of images into zarr files

images_to_zarr

A Python module to efficiently bulk-convert large collections of heterogeneous images (FITS, PNG, JPEG, TIFF) into sharded Zarr v3 stores for fast analysis and cloud-native workflows.

Features

• Multi-format support: FITS, PNG, JPEG, TIFF images
• Consistent NCHW format: All images stored in (batch, channels, height, width) format for ML workflows
• Direct memory conversion: Convert numpy arrays directly to Zarr without intermediate files
• Efficient storage: Sharded Zarr v3 format with configurable compression
• Metadata preservation: Combines image data with tabular metadata
• Parallel processing: Multi-threaded conversion for large datasets
• Cloud-friendly: S3-compatible storage backend
• Visual inspection: Built-in plotting tools to sample and display stored images
• Easy inspection: Built-in tools to analyze converted stores

Installation

From PyPI

pip install images-to-zarr

After installation, the CLI command images_to_zarr will be available system-wide.

From source

git clone https://github.com/gomezzz/images_to_zarr.git
cd images_to_zarr
pip install -e .

Using conda

conda env create -f environment.yml
conda activate img2zarr
pip install -e .

Quick Start

Command Line Interface

Convert image folders to Zarr:

# Basic conversion with metadata
images_to_zarr convert /path/to/images --metadata metadata.csv --out /output/dir

# Basic conversion without metadata (filenames only)
images_to_zarr convert /path/to/images --out /output/dir

# Convert images to Zarr with metadata
images_to_zarr convert /path/to/images --metadata metadata.csv --out /output/dir

# Convert without metadata (filenames only)
images_to_zarr convert /path/to/images --out /output/dir

# Advanced options with resize
images_to_zarr convert /path/to/images1 /path/to/images2 \
    --metadata metadata.csv \
    --out /output/dir \
    --recursive \
    --workers 16 \
    --fits-ext 0 \
    --chunk-shape 1,512,512 \
    --compressor zstd \
    --clevel 5 \
    --resize 256,256 \
    --interpolation-order 1 \
    --overwrite

Inspect a Zarr store:

images_to_zarr inspect /path/to/store.zarr

Python API

from images_to_zarr import convert, inspect, display_sample_images
from images_to_zarr.convert import convert_from_memory
import numpy as np
from pathlib import Path

# Convert images to Zarr with metadata
zarr_path = convert(
    folders=["/path/to/images"],
    recursive=True,
    metadata="/path/to/metadata.csv",  # Optional
    output_dir="/output/dir",
    num_parallel_workers=8,
    chunk_shape=(1, 256, 256),
    compressor="zstd",
    clevel=4
)

# Convert images to Zarr with automatic resizing
zarr_path = convert(
    folders=["/path/to/images"],
    recursive=True,
    metadata="/path/to/metadata.csv",  # Optional
    output_dir="/output/dir",
    resize=(256, 256),  # Resize all images to 256x256
    interpolation_order=1,  # Bi-linear interpolation
    num_parallel_workers=8,
    chunk_shape=(1, 256, 256),
    compressor="zstd",
    clevel=4
)

# Convert images to Zarr without metadata (filenames only)
zarr_path = convert(
    folders=["/path/to/images"],
    recursive=True,
    metadata=None,  # or simply omit this parameter
    output_dir="/output/dir"
)

# Convert numpy arrays directly to Zarr (memory-to-zarr conversion)
# Images must be in NCHW format: (batch, channels, height, width)
images = np.random.rand(100, 3, 224, 224).astype(np.float32)  # 100 RGB images
zarr_path = convert_from_memory(
    images=images,
    output_dir="/output/dir",
    compressor="lz4",
    overwrite=True
)

# Convert with custom metadata for memory conversion
metadata = [{"id": i, "source": "generated"} for i in range(100)]
zarr_path = convert(
    output_dir="/output/dir",
    images=images,
    image_metadata=metadata,
    chunk_shape=(10, 224, 224),  # Chunk 10 images together
    overwrite=True
)

# Inspect the result
inspect(zarr_path)

# Display random sample images from the store (with auto-normalization for .fits)
from images_to_zarr import display_sample_images
display_sample_images(zarr_path, num_samples=6, figsize=(15, 10))

# Save sample images to file
display_sample_images(zarr_path, num_samples=4, save_path="samples.png")

Usage

Metadata CSV Format

The metadata CSV file is optional. If provided, it must contain at least a filename column. Additional columns are preserved:

filename,source_id,ra,dec,magnitude
image001.fits,12345,123.456,45.678,18.5
image002.png,12346,124.567,46.789,19.2
image003.jpg,12347,125.678,47.890,17.8

If no metadata file is provided, metadata will be automatically created from the filenames:

# Convert without metadata - will use filenames only
images_to_zarr convert /path/to/images --out /output/dir

# Convert with metadata
images_to_zarr convert /path/to/images --metadata metadata.csv --out /output/dir

Supported Image Formats

• FITS (.fits, .fit): Astronomical images with flexible HDU support
• PNG (.png): Lossless compressed images
• JPEG (.jpg, .jpeg): Compressed photographic images
• TIFF (.tif, .tiff): Uncompressed or losslessly compressed images

FITS Extension Handling

# Use primary HDU (default)
convert(..., fits_extension=None)

# Use specific extension by number
convert(..., fits_extension=1)

# Use extension by name
convert(..., fits_extension="SCI")

# Combine multiple extensions
convert(..., fits_extension=[0, 1, "ERR"])

Image Resizing

When dealing with images of different sizes, you can use the resize functionality:

# Resize all images to 512x512 using bi-linear interpolation
convert(
    folders=["/path/to/images"],
    output_dir="/output/dir",
    resize=(512, 512),
    interpolation_order=1  # 0=nearest, 1=linear, 2=quadratic, etc.
)

# If resize is not specified, all images must have the same dimensions
# or an error will be raised

Interpolation orders:

• 0: Nearest-neighbor (fastest, lowest quality)
• 1: Bi-linear (default, good balance)
• 2: Bi-quadratic
• 3: Bi-cubic (slower, higher quality)
• 4: Bi-quartic
• 5: Bi-quintic (slowest, highest quality)

Configuration Options

Parameter	Description	Default
chunk_shape	Zarr chunk dimensions (n_images, height, width)	(1, 256, 256)
compressor	Compression codec (zstd, lz4, gzip, etc.)	"lz4"
clevel	Compression level (1-9)	1
num_parallel_workers	Number of processing threads	8
recursive	Scan subdirectories recursively	False
fits_extension	FITS HDU(s) to read (int, str, or sequence)	None (uses 0)
resize	Resize images to (height, width)	None
interpolation_order	Resize interpolation order (0-5)	1 (bi-linear)
overwrite	Overwrite existing store if present	False

Output Structure

output_dir/
├── images.zarr/              # Main Zarr store (if output_dir doesn't end with .zarr)
│   ├── images/              # Image data arrays
│   └── .zarray, .zgroup     # Zarr metadata
└── images_metadata.parquet  # Combined metadata

Note: If you specify an output directory ending with .zarr (e.g., /path/to/my_dataset.zarr), that path will be used directly as the Zarr store, creating a cleaner output structure.

Zarr Store Contents

• images: Main array containing all image data
• Attributes: Store metadata, compression info, creation parameters
• Chunks: Sharded for efficient cloud access

Metadata Parquet

Combined metadata includes:

• Original CSV columns
• Image-specific metadata (dimensions, dtype, file size)
• Processing statistics (min/max/mean values)

Performance Tips

1. Chunk size: Match your typical access patterns

   • Single image access: (1, H, W)
   • Batch processing: (B, H, W) where B > 1

2. Compression: Balance speed vs. size

   • Fast: lz4 with low compression level
   • Compact: zstd with high compression level

3. Parallelism: Scale with your I/O capacity

   • Local SSD: 8-16 workers
   • Network storage: 4-8 workers
   • S3: 16-32 workers

4. Memory: Monitor for large images

   • Consider smaller chunk sizes for very large images
   • Reduce batch size if memory usage is high

Inspection Output Example

================================================================================
SUMMARY STATISTICS  
================================================================================
Total images across all files: 104,857,600
Total storage size: 126,743.31 MB
Image dimensions: (3, 256, 256)
Data type: uint8
Compression: lz4 (level 1)

Format distribution:
  FITS: 60,000,000 (57.2%)
  PNG: 30,000,000 (28.6%) 
  JPEG: 10,000,000 (9.5%)
  TIFF: 4,857,600 (4.6%)

Original data type distribution:
  uint8: 78.0%
  int16: 12.0%
  float32: 10.0%
================================================================================

Image Display and Visualization

The display_sample_images function provides intelligent visualization with automatic normalization:

from images_to_zarr import display_sample_images

# Display with automatic normalization (handles .fits files with arbitrary ranges)
display_sample_images("/path/to/store.zarr", num_samples=6)

Error Handling

The library provides robust error handling:

• Missing files: Warnings logged, processing continues
• Corrupted images: Replaced with zero arrays, errors recorded in metadata
• Incompatible formats: Clear error messages with suggested fixes
• Storage issues: Detailed error reporting for disk/network problems

Logging Configuration

from images_to_zarr import configure_logging

# Enable detailed logging
configure_logging(enable=True, level="DEBUG")

# Disable for production
configure_logging(enable=False)

Contributing

1. Fork the repository
2. Create a feature branch (git checkout -b feature/amazing-feature)
3. Commit your changes (git commit -m 'Add amazing feature')
4. Push to the branch (git push origin feature/amazing-feature)
5. Open a Pull Request

Development Setup

git clone https://github.com/username/images_to_zarr.git
cd images_to_zarr
conda env create -f environment.yml
conda activate img2zarr
pip install -e ".[dev]"

# Run tests
pytest

# Format code
black .

# Check linting
flake8

License

This project is licensed under the MIT License - see the LICENSE file for details.

Acknowledgments

• Built on Zarr for array storage
• Uses Astropy for FITS support
• Inspired by the needs of astronomical data processing pipelines

Channel Order and Format Consistency

All images are automatically converted to NCHW format (batch, channels, height, width) for consistency across different input formats:

• 2D grayscale: (H, W) → (1, 1, H, W)
• 3D RGB (HWC): (H, W, C) → (1, C, H, W)
• 3D CHW: (C, H, W) → (1, C, H, W)
• 4D batched: Already in NCHW format

The library intelligently detects the input format:

• Images with ≤4 channels in the last dimension are treated as HWC (Height-Width-Channels)
• Images with >4 channels in the last dimension are treated as CHW (Channels-Height-Width)
• FITS files and other scientific formats are handled appropriately

This ensures consistent tensor shapes for machine learning workflows while preserving the original data.

Direct Memory Conversion

Convert numpy arrays directly to Zarr without saving intermediate files:

import numpy as np
from images_to_zarr.convert import convert_from_memory

# Your image data (must be 4D NCHW format)
images = np.random.rand(1000, 3, 256, 256).astype(np.float32)

# Convert directly to zarr
zarr_path = convert_from_memory(
    images=images,
    output_dir="./data",
    compressor="lz4",
    chunk_shape=(100, 256, 256),  # Chunk 100 images together
    overwrite=True
)