Metadata-Version: 2.1
Name: selfies
Version: 1.0.4
Summary: SELFIES (SELF-referencIng Embedded Strings) is a general-purpose, sequence-based, robust representation of semantically constrained graphs.
Home-page: https://github.com/aspuru-guzik-group/selfies
Author: Mario Krenn
Author-email: mario.krenn@utoronto.ca, alan@aspuru.com
License: UNKNOWN
Description: # SELFIES
        
        [![GitHub release](https://img.shields.io/github/release/aspuru-guzik-group/selfies.svg)](https://GitHub.com/aspuru-guzik-group/selfies/releases/)
        ![versions](https://img.shields.io/pypi/pyversions/selfies.svg)
        [![License](https://img.shields.io/badge/License-Apache%202.0-blue.svg)](https://opensource.org/licenses/Apache-2.0)
        [![Maintenance](https://img.shields.io/badge/Maintained%3F-yes-blue.svg)](https://GitHub.com/aspuru-guzik-group/selfies/graphs/commit-activity)
        [![GitHub issues](https://img.shields.io/github/issues/aspuru-guzik-group/selfies.svg)](https://GitHub.com/aspuru-guzik-group/selfies/issues/)
        [![Documentation Status](https://readthedocs.org/projects/selfies/badge/?version=latest)](http://selfies.readthedocs.io/?badge=latest)
        [![GitHub contributors](https://img.shields.io/github/contributors/aspuru-guzik-group/selfies.svg)](https://GitHub.com/aspuru-guzik-group/selfies/graphs/contributors/)
        
        
        **Self-Referencing Embedded Strings (SELFIES): A 100% robust molecular string representation**<br>
        _Mario Krenn, Florian Haese, AkshatKumar Nigam, Pascal Friederich, Alan Aspuru-Guzik_<br>
        [*Machine Learning: Science and Technology* **1**, 045024 (2020)](https://iopscience.iop.org/article/10.1088/2632-2153/aba947), [extensive blog post January 2021](https://aspuru.substack.com/p/molecular-graph-representations-and).<br>
        [Talk on youtube about SELFIES](https://www.youtube.com/watch?v=CaIyUmfGXDk).<br>
        Major contributors since v1.0.0: _[Alston Lo](https://github.com/aspuru-guzik-group/selfies/commits?author=alstonlo) and [Seyone Chithrananda](https://github.com/seyonechithrananda)_<br>
        Chemistry Advisor: [Robert Pollice](https://scholar.google.at/citations?user=JR2N3JIAAAAJ)
        
        A main objective is to use SELFIES as direct input into machine learning models,<br>
        in particular in generative models, for the generation of molecular graphs<br>
        which are syntactically and semantically valid.
        
        <center><img src="https://github.com/aspuru-guzik-group/selfies/blob/master/examples/VAE_LS_Validity.png" alt="SELFIES validity in a VAE latent space" width="666px"></center>
        
        
        ## Installation
        Use pip to install ``selfies``.
        
        ```bash
        pip install selfies
        ```
        
        To check if the correct version of ``selfies`` is installed, use
        the following pip command. 
        
        ```bash
        pip show selfies
        ```
        
        To upgrade to the latest release of ``selfies`` if you are using an 
        older version, use the following pip command. Please see the 
        [CHANGELOG](https://github.com/aspuru-guzik-group/selfies/blob/master/CHANGELOG.md) 
        to review the changes between versions of `selfies`:
        
        ```bash
        pip install selfies --upgrade 
        ```
        
        ## Documentation
        
        The documentation can be found on
        [ReadTheDocs](https://selfies.readthedocs.io/en/latest/).
        Alternatively, it can be built from the ``docs/`` directory.
        
        ## Usage
        
        ### Standard Functions
        
        The ``selfies`` library has eight standard functions:
        
        | Function | Description |
        | -------- | ----------- |
        | ``selfies.encoder`` | Translates a SMILES into an equivalent SELFIES. |
        | ``selfies.decoder`` | Translates a SELFIES into an equivalent SMILES. |
        | ``selfies.len_selfies`` | Returns the (symbol) length of a SELFIES.  |
        | ``selfies.split_selfies`` | Splits a SELFIES into its symbols. |
        | ``selfies.get_alphabet_from_selfies`` | Builds an alphabet of SELFIES symbols from an iterable of SELFIES. |
        | ``selfies.get_semantic_robust_alphabet`` | Returns a subset of all SELFIES symbols that are semantically constrained. |
        | ``selfies.selfies_to_encoding`` | Converts a SELFIES into a label and/or one-hot encoding. |
        | ``selfies.encoding_to_selfies`` | Converts a label or one-hot encoding into a SELFIES. |
        
        Please read the documentation for more detailed descriptions of these
        functions, and to view the advanced functions, which allow users to
        customize the SELFIES language.
        
        ### Examples
        
        #### Translation between SELFIES and SMILES representations:
        
        ```python
        import selfies as sf
        
        benzene = "c1ccccc1"
        
        # SMILES --> SELFIES translation
        encoded_selfies = sf.encoder(benzene)  # '[C][=C][C][=C][C][=C][Ring1][Branch1_2]'
        
        # SELFIES --> SMILES translation
        decoded_smiles = sf.decoder(encoded_selfies)  # 'C1=CC=CC=C1'
        
        len_benzene = sf.len_selfies(encoded_selfies)  # 8
        
        symbols_benzene = list(sf.split_selfies(encoded_selfies))
        # ['[C]', '[=C]', '[C]', '[=C]', '[C]', '[=C]', '[Ring1]', '[Branch1_2]']
        ```
        
        #### Integer and one-hot encoding SELFIES:
        In this example we first build an alphabet
        from a dataset of SELFIES, and then convert a SELFIES into a
        padded, label-encoded representation. Note that we use the
        ``'[nop]'`` ([no operation](https://en.wikipedia.org/wiki/NOP_(code) ))
        symbol to pad our SELFIES, which is a special SELFIES symbol that is always
        ignored and skipped over by ``selfies.decoder``, making it a useful
        padding character.
        
        ```python
        import selfies as sf
        
        dataset = ['[C][O][C]', '[F][C][F]', '[O][=O]', '[C][C][O][C][C]']
        alphabet = sf.get_alphabet_from_selfies(dataset)
        alphabet.add('[nop]')  # '[nop]' is a special padding symbol
        alphabet = list(sorted(alphabet))
        print(alphabet)  # ['[=O]', '[C]', '[F]', '[O]', '[nop]']
        
        pad_to_len = max(sf.len_selfies(s) for s in dataset)  # 5
        symbol_to_idx = {s: i for i, s in enumerate(alphabet)}
        
        # SELFIES to label encode
        dimethyl_ether = dataset[0]  # '[C][O][C]'
        
        # [1, 3, 1, 4, 4]
        print(sf.selfies_to_encoding(dimethyl_ether,
                                     vocab_stoi=symbol_to_idx,
                                     pad_to_len=pad_to_len,
                                     enc_type='label'))
                                     
        # [[0, 1, 0, 0, 0], [0, 0, 0, 1, 0], [0, 1, 0, 0, 0], [0, 0, 0, 0, 1], [0, 0, 0, 0, 1]]
        print(sf.selfies_to_encoding(dimethyl_ether,
                                     vocab_stoi=symbol_to_idx,
                                     pad_to_len=pad_to_len,
                                     enc_type='one_hot'))
        ```
        
        ### More Examples
        
        * More examples can be found in the ``examples/`` directory, including a
        [variational autoencoder that runs on the SELFIES](https://github.com/aspuru-guzik-group/selfies/tree/master/examples/vae_example) language.
        * This [ICLR2020 paper](https://arxiv.org/abs/1909.11655) used SELFIES in a
        genetic algorithm to achieve state-of-the-art performance for inverse design,
        with the [code here](https://github.com/aspuru-guzik-group/GA).
        * SELFIES allows for [highly efficient exploration and interpolation of the chemical space](https://chemrxiv.org/articles/preprint/Beyond_Generative_Models_Superfast_Traversal_Optimization_Novelty_Exploration_and_Discovery_STONED_Algorithm_for_Molecules_using_SELFIES/13383266), with a [deterministic algorithms, see code](https://github.com/aspuru-guzik-group/stoned-selfies).
        * We use SELFIES for [Deep Molecular dreaming](https://arxiv.org/abs/2012.09712), a new generative model inspired by interpretable neural networks in computational vision. See the [code of PASITHEA here](https://github.com/aspuru-guzik-group/Pasithea).
        * Kohulan Rajan, Achim Zielesny, Christoph Steinbeck show in two papers that SELFIES outperforms other representations in [img2string](https://link.springer.com/article/10.1186/s13321-020-00469-w) and [string2string](https://chemrxiv.org/articles/preprint/STOUT_SMILES_to_IUPAC_Names_Using_Neural_Machine_Translation/13469202/1) translation tasks, see the codes of [DECIMER](https://github.com/Kohulan/DECIMER-Image-to-SMILES) and [STOUT](https://github.com/Kohulan/Smiles-TO-iUpac-Translator). 
        
        
        ## Handling invalid inputs
        If an invalid input is presented to the encoder or decoder, the return value is `None`.
        The error can be analysed by using the `encoder(...,print_error=True)` option.
        ```python
        import selfies as sf
        invalid_smiles="C[C@H](O)[C@@(*)C1=CC=CC=C1"
        selfies_string=sf.encoder(invalid_smiles) 
        
        if selfies_string==None:
            selfies_string=sf.encoder(invalid_smiles,print_error=True) 
            # 'Encoding error 'C[C@H](O)[C@@(*)C1=CC=CC=C1': wildcard atom '*' not supported.'
        ```
        
        ## Tests
        SELFIES uses `pytest` with `tox` as its testing framework.
        All tests can be found in  the `tests/` directory. To run the test suite for
        SELFIES, install ``tox`` and run:  
        
        ```bash
        tox
        ```
        
        By default, SELFIES is tested against a random subset
        (of size ``dataset_samples=100000``) on various datasets:
        
         * 130K molecules from [QM9](https://www.nature.com/articles/sdata201422)
         * 250K molecules from [ZINC](https://en.wikipedia.org/wiki/ZINC_database)
         * 50K molecules from [non-fullerene acceptors for organic solar cells](https://www.sciencedirect.com/science/article/pii/S2542435117301307)
         * 8K molecules from [Tox21](http://moleculenet.ai/datasets-1) in MoleculeNet
         * 93K molecules from PubChem [MUV](http://moleculenet.ai/datasets-1) in MoleculeNet
         * 27M molecules from the [eMolecules Plus Database](https://www.emolecules.com/info/plus/download-database).
           Due to its large size, this dataset is not included on the repository. To run tests 
           on it, please download the dataset in the ``tests/test_sets`` directory 
           and enable its pytest at ``tests/test_on_emolecules.py``. 
        
        Other tests are random and repeated ``trials`` number of times.
        These can be specified as arguments
        
        ```bash
        tox -- --trials 100 --dataset_samples 100
        ```
        
        where ``--trials=100000`` and ``--dataset_samples=100000`` by default. Note that
        if ``dataset_samples`` is negative or exceeds the length of the dataset,
        the whole dataset is used.
        
        ## Version History
        See [CHANGELOG](https://github.com/aspuru-guzik-group/selfies/blob/master/CHANGELOG.md).
        
        ## Credits
        
        We thank Jacques Boitreaud, Andrew Brereton, Matthew Carbone (x94carbone), Nathan Frey (ncfrey), Theophile Gaudin,
        HelloJocelynLu, Hyunmin Kim (hmkim), Minjie Li, Vincent Mallet, Alexander Minidis (DocMinus), Kevin Ryan (LeanAndMean),
        Benjamin Sanchez-Lengeling, and Zhenpeng Yao for their suggestions and bug reports,
        and Robert Pollice for chemistry advices.
        
        ## License
        
        [Apache License 2.0](https://choosealicense.com/licenses/apache-2.0/)
        
Platform: UNKNOWN
Classifier: Programming Language :: Python :: 3
Classifier: Programming Language :: Python :: 3.5
Classifier: Programming Language :: Python :: 3.6
Classifier: Programming Language :: Python :: 3.7
Classifier: Programming Language :: Python :: 3.8
Classifier: Programming Language :: Python :: 3 :: Only
Classifier: License :: OSI Approved :: Apache Software License
Classifier: Operating System :: OS Independent
Requires-Python: >=3.5
Description-Content-Type: text/markdown
