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Bio Datasets

Bringing bio (molecules and more) to the HuggingFace Datasets library.

This (unofficial!) extension to Datasets is designed to make the following things as easy as possible:

  1. efficient storage of biological data for ML
  2. low-overhead loading and standardisation of data into ML-ready python objects
  3. sharing of datasets large and small

We aim to do these three things and no more, leaving you to get on with the science!

Efficient conversion between storage and usage formats

The best format for storing data is typically not the most convenient format for data to be loaded into for downstream applications. The Datasets library abstracts the details of these choices and the logic for converting between formats into Feature classes, dictating how data of particular types should be stored and loaded. We extend the Datasets library by creating Feature types for optimised storage and loading of biological data, starting with biomolecular structures.

The main formats we support for storing and loading biomolecular structure data are:

Feature name Storage format Loaded as (controlled by load_as feature kwarg)
AtomArrayFeature arrays of cartesian coordinates and annotations biotite.structure.AtomArray (default) / bio_datasets.BiomoleculeChain / bio_datasets.BiomoleculeComplex (bio_datasets classes are lightweight wrappers around AtomArray)
StructureFeature compressed byte string encoded file format embedded into parquet columns: PDB / mmCIF / binaryCIF biotite.structure.AtomArray / bio_datasets.BiomoleculeChain / bio_datasets.BiomoleculeComplex

We also provide protein-specific versions of these features for protein structure data, supporting protein-specific storage formats (like foldcomp) and loaded python objects:

Feature name Storage format Loaded as
ProteinAtomArrayFeature arrays of cartesian or (experimental: discretised internal) coordinates and annotations biotite.structure.AtomArray / bio_datasets.ProteinChain / bio_datasets.ProteinComplex (default)
ProteinStructureFeature compressed byte string encoded file format embedded into parquet columns: PDB / mmCIF / binaryCIF / foldcomp biotite.structure.AtomArray / bio_datasets.ProteinChain / bio_datasets.ProteinComplex (default)

Installation with pip

pip install datasets-bio

Usage

Loading data from the Hub

In the Datasets library, datasets are associated with metadata annotations describing the feature types present in the dataset, and how those feature types should be stored and loaded.

This makes it easy to share datasets in efficient storage formats, while allowing people who download the dataset to directly access the data in a convenient format for downstream use.

To illustrate, we provide examples of datasets pre-configured with Bio Datasets Feature types that can be downloaded from the hub.

Generic biomolecular structure data

from bio_datasets import load_dataset

dataset = load_dataset(
    "biodatasets/pdb",
    split="train",
)
ex = dataset[0]
print(type(ex["structure"]))  # a dict with keys `id` and `structure` (a `biotite.structure.AtomArray`)
biotite.structure.AtomArray

Protein structure data (e.g. from afdb)

from bio_datasets import load_dataset

dataset = load_dataset(
    "biodatasets/afdb_e_coli",
    split="train",
)
ex = dataset[0]  # a dict with keys `name` and `structure` (a `biotite.structure.AtomArray` wrapped in a `bio_datasets.ProteinChain` object for standardisation.)
print(type(ex["structure"]))
<class 'bio_datasets.structure.protein.protein.ProteinChain'>

That's it: when you access data from a dataset with preset Bio Datasets feature types, the datapoints that it returns will be Python dictionaries containing your Protein data formatted as a bio_datasets.ProteinChain object (basically a biotite AtomArray with some added convenience methods for Protein ML.)

The trick is that the data was stored together with the required Feature type information, which we can inspect directly:

print(dataset.info.features)
{'name': Value(dtype='string', id=None),
 'structure': ProteinStructureFeature(requires_encoding=True, requires_decoding=True, decode=True, load_as='chain', constructor_kwargs=None, load_assembly=False, fill_missing_residues=False, include_bonds=False, with_occupancy=False, with_b_factor=True, with_atom_id=False, with_charge=False, encode_with_foldcomp=False, compression=None)}

To summarise: this dataset contains two features: 'name', which is a string, and 'structure' which is a bio_datasets.ProteinStructureFeature. Features of this type will automatically be loaded as bio_datasets.Protein instances when the Bio Datasets library is installed; and as dictionaries containing the fields path, bytes (the file contents) and type (the file format e.g. 'pdb', 'cif', etc.) fields when loaded with datasets.load_dataset by a user who does not have Bio Datasets installed.

We can also inspect the raw data format used for storage by discarding the feature information:

dataset.info.features = None
dataset[0]["structure"]  # a dictionary with key bytes whose value is the foldcomp byte string

Creating a dataset with bio feature types

Building and sharing datasets from local files

To streamline the processes of building your own datasets from local files, we provide some utility classes for building datasets from standard formats. For example suppose you have a local directory containing PDB files. You want to write an efficient data loader, and ideally to reduce the size of the directory to make it easier to share with your collaborators. bio-datasets allows you to achieve these two things with almost no effort.

Fully-flexible dataset construction

If your local data doesn't fit the format assumed by ProteinStructureFolder, but you still want a way to create a Dataset instance (for example to convert your local data into a more efficient storage format for sharing, or to exploit Dataset's fast memory-mapped retrieval), you simply need to configure a Dataset constructor with information on your Feature types:

This feature configuration is performed by creating a bio_datasets.Features object mapping column names to feature types.

Each Feature type supports various configuration options (see details in _init_ methods) controlling the formats in which data is stored and loaded.

For example, using a generator-based Dataset constructor:

from bio_datasets import Dataset, Features, ProteinStructureFeature


def examples_generator(pdb_file_list):
    for file_path in pdb_file_list:
        yield {"structure": {"path": file_path}}  # generate examples in 'raw' format


# create a dataset which will save data to disk as a foldcomp-encoded byte string, but which will automatically
# decode that data to biotite atom arrays during loading / iteration
features = Features(structure=ProteinStructureFeature(encode_with_foldcomp=True))
ds = Dataset.from_generator(examples_generator, gen_kwargs={"pdb_file_list": pdb_file_list}, features=features)
ds[0]

# share your bio dataset to the HuggingFace hub!
ds.push_to_hub(HUB_REPO_ID)

The examples_generator function yields single datapoints in unprocessed formats compatible with the corresponding feature:

In this case the unprocessed data for the 'structure' column is passed as a python dictionary containing a single key 'path' whose value is the path to a PDB file. Refer to the documentation of individual Feature types for more information on supported input formats. (Under the hood these will be encoded via feature.encode_example).

Performance tips: choose Feature types to trade off between efficiency of storage and loading

bio_datasets.StructureFeature feature data is stored internally as PDB format byte-strings (optionally compressed with foldcomp or gzip). bio_datasets automatically handles conversion from this format to the biotite AtomArray format for downstream processing. Of course, parsing the PDB format to biotite format involves some overhead (though it's still possible to iterate over ~100 pdb files a second; and we'll automatically load files using fastpdb if you have it installed)

If you want even faster processing, we also support storing data in a native array format that supports blazingly fast iteration over fully featurised samples. Let's convert the bio_datasets.StructureFeature data to the bio_datasets.AtomArrayFeature type, and compare iteration speed:

import timeit
from bio_datasets import AtomArrayFeature, Features, Value, load_dataset

dataset = load_dataset(
    "biodatasets/afdb_e_coli",
    split="train",
)
pdb_time = timeit.timeit(stmt="""[ex for ex in dataset]""", number=1, globals=globals())
def convert_structure_to_array(ex, features):
    return features.encode_example(ex)

new_features = Features(name=Value("string"), structure=AtomArrayFeature())
array_dataset = dataset.map(convert_structure_to_array, features=new_features, fn_kwargs={"features": new_features})
array_time = timeit.timeit(stmt="""[ex for ex in array_dataset]""", number=1, globals=globals())

print(
  f"Iterated over {len(dataset)} examples in "
  f"{pdb_time:.1f}s with PDB storage vs {array_time:.1f}s with array storage\n"
  f" i.e. {len(dataset)/pdb_time:.1f} samples/s vs {len(dataset)/array_time:.1f} samples/s"
)
Iterated over 8726 examples in 47.5s with PDB storage vs 7.0s with array storage
 i.e. 183.6 samples/s vs 1237.8 samples/s

All of the Datasets library's methods for faster loading, including batching and multiprocessing can also be applied to further optimise performance!

To combine the fast iteration offered by array-based storage with foldcomp-style compression, we offer an experimental option to store structure data in a foldcomp-style discretised internal coordinate-based representation.

Sharing data to the hub

ds.push_to_hub will automatically save information about the Feature types stored in the dataset. If a user with bio-datasets installed downloads the dataset, their bio data will then automatically be decoded in the way specified by the Features.

Creating your own feature types

Features require specification of three things: (i) how the data is stored (ii) how the data is loaded (ii) how the feature configuration is serialised and stored as metadata

These functionalities are handled by methods of the CustomFeature base class. To implement a new feature, inherit from CustomFeature and implement call, _encode_example and _decode_example.

call is invoked by get_nested_type.

Serialisation will be performed automatically by dataclasses asdict - to customise?

TODO: example

Roadmap

  • Support for other biological data types: MD, single cell / omics, ...

Contributions

We would love to receive contributions of code (e.g. new feature types!), suggestions for new data formats/feature types, and sharing of compatible bio datasets e.g. to the HuggingFace Hub