Code for working on computational phonology and morphology in Python.
This package is based on code developed by Caleb Belth during the course of his PhD; the title of his dissertation, Towards an Algorithmic Account of Phonological Rules and Representations, serves as the origin for the repository's name algophon.
The package is under active development! The PyPI distribution and documentation are updated as the project progresses. The package includes:
- Handy tools for working with strings of phonological segments.
- Implementations of computational learning models.
Suggestions are welcome!
pip install algophon
The code at the top level of the package provides some nice functionality for easily working with strings of phonological segments.
The following examples assume you have imported the appropriate classes:
>>> from algophon import Seg, SegInv, SegStr, NatClass
A class to represent a phonological segment.
You are unlikely to be creating Seg
objects yourself very often. They will usually be constructed internally by other parts of the package (in particular, see SegInv
and SegStr
). However, if you ever need to, creating a Seg
object requires the following arguments:
ipa
: astr
IPA symbolfeatures
(optional): adict
of features mapping to their corresponding values
>>> seg = Seg(ipa='i', features={'syl': '+', 'voi': '+', 'stri': '0'})
What is important to know is how Seg
objects behave, and why they are handy.
First, in the important respects Seg
behaves like the str
IPA segment used to create it.
If you print
a Seg
object, it will print its IPA:
>>> print(seg)
i
If you compare a Seg
object to a str
, it will behave like it is the IPA symbol:
>>> print(seg == 'i')
True
>>> print(seg == 'e')
False
A Seg
object hashes to the same value as its IPA symbol:
>>> print(len({seg, 'i'}))
1
>>> print('i' in {seg}, seg in {'i'})
True True
Second, in the important respects Seg
behaves like a feature bundle (see also the other classes, where other benefits will become clear).
>>> print(seg.features['syl'])
+
Third, Seg
handles IPA symbols that are longer than one Unicode char.
>>> tsh = Seg(ipa='t͡ʃ')
>>> print(tsh)
t͡ʃ
>>> print(len(tsh))
1
>>> from algophon.symbols import LONG # see description of symbols below
>>> long_i = Seg(ipa=f'i{LONG}')
>>> print(long_i)
iː
>>> print(len(long_i))
1
A class to represent an inventory of phonological segments (Seg objects).
A SegInv
object is a collection of Seg
objects. A SegInv
requires no arguments to construct, though it provides two optional arguments:
ipa_file_path
: astr
pointing to a file of segment-feature mappings.sep
: astr
specifying the column separator of theipa_file_path
file.
By default, SegInv
uses Panphon (Mortensen et. al., 2016) features. The optional parameters allow you to use your own features. The file at ipa_file_path
must be formatted like this:
- The first row must be a header of feature names, separated by the
sep
(by default,\t
) - The first column must contain the segment IPAs (the header row can have anything, e.g.,
SEG
) - The remaining columns (non-first row) must contain the feature values.
When a SegInv
object is created, it is empty:
>>> seginv = SegInv()
>>> seginv
SegInv of size 0
You can add segments by the add
, add_segments
, and add_segments_by_str
methods:
>>> seginv.add('i')
>>> print(seginv.segs)
{i}
>>> seginv.add_segs({'p', 'b', 't', 'd'})
>>> print(seginv.segs)
{b, t, d, i, p}
>>> seginv.add_segs_by_str('eː n t j ə') # segments in str must be space-separated
>>> print(seginv.segs)
{b, t, d, i, j, n, p, ə, eː}
The reason that add_segs_by_str
requires the segments to be space-separated is because not all IPA symbols are only one char (e.g., 'eː'
). Moreover, this is consistent with the Sigmorphon challenges data format commonly used in morphophonology tasks.
These add*
methods automatically create Seg
objects and assign them features
based on either Panphon (default) or the ipa_file_path
file.
>>> print(seginv['eː'].features)
{'syl': '+', 'son': '+', 'cons': '-', 'cont': '+', 'delrel': '-', 'lat': '-', 'nas': '-', 'strid': '0', 'voi': '+', 'sg': '-', 'cg': '-', 'ant': '0', 'cor': '-', 'distr': '0', 'lab': '-', 'hi': '-', 'lo': '-', 'back': '-', 'round': '-', 'velaric': '-', 'tense': '+', 'long': '+', 'hitone': '0', 'hireg': '0'}
This also demonstrates that seginv
operates like a dictionary in that you can retrieve and check the existence of segments by their IPA.
>>> 'eː' in seginv
True
A class to represent a sequence of phonological segments (Seg objects).
The class SegStr
allows for handling several tricky aspects of IPA sequences. It is common practice to represent strings of IPA sequences in a space-separated fashion such that, for example, [eːntjə] is represented 'eː n t j ə'
.
Creating a SegStr
object requires the following arguments:
segs
: a collection of segments, which can be in any of the following formats:- str of IPA symbols, where each symbol is separated by a space ' ' (most common)
- list of IPA symbols
- list of Seg objects
seginv
: aSegInv
object
>>> seginv = SegInv() # init SegInv
>>> seq = SegStr('eː n t j ə', seginv)
>>> print(seq)
eːntjə
Creating the SegStr
object automatically adds the segments in the object to the SegInv
object.
>>> print(seginv.segs)
{ə, t, n, j, eː}
For clean visualization, SegStr
displays the sequence of segments without spaces, as print(seq)
shows above. But internally a SegStr
object knows what the segments are:
>>> print(len(seq))
5
>>> seq[0]
eː
>>> type(seq[0]) # indexing returns a Seg object
<class 'algophon.seg.Seg'>
>>> seq[-2:]
jə
>>> type(seq[-2:]) # slicing returns a new SegStr object
<class 'algophon.segstr.SegStr'>
>>> seq[-2:] == 'j ə' # comparison to str objects works as expected
True
>>> seq[-2:] == 'ə n'
False
SegStr
also implements equivalents of useful str
methods.
>>> seq.endswith('j ə')
True
>>> dim_sufx = seq[-2:]
>>> seq.endswith(dim_sufx)
True
>>> seq.startswith(seq[:-2])
True
A SegStr
object hashes to the value of its (space-separated) string:
>>> len({seq, 'eː n t j ə'})
1
>>> seq in {'eː n t j ə'}
True
A class to represent a Natural class, in the sense of sets of segments represented intensionally as conjunctions of features.
>>> son = NatClass(feats={'+son'}, seginv=seginv)
>>> son
[+son]
>>> 'ə' in son
True
>>> 'n' in son
True
>>> 't' in son
False
The class also allows you to get the natural class's extension and the extension's complement, relative to the SegInv
(in our example, only {ə, t, n, j, eː}
are in seginv
):
>>> son.extension()
{eː, j, ə, n}
>>> son.extension_complement()
{t}
You can also retrieve an extension (complement) directly from a SegInv
object without creating a NatClass
obj:
>>> seginv.extension({'+syl'})
{ə, eː}
>>> seginv.extension_complement({'+syl'})
{j, t, n}
The symbols
module (technically just a file...) contains a number of constant variables that store some useful symbols:
LWB = '⋊'
RWB = '⋉'
SYLB = '.'
MORPHB = '-'
BOUNDARIES = [LWB, RWB, SYLB, MORPHB]
PRIMARY_STRESS = 'ˈ'
SEC_STRESS = 'ˌ'
LONG = 'ː'
NASALIZED = '\u0303' # ◌̃
UNDERSPECIFIED = '0'
UNK = '?'
NEG = '¬'
EMPTY = '_'
FUNCTION_COMPOSITION = '∘'
These can be accessed like this:
>>> from algophon.symbols import *
>>> NASALIZED
'̃'
>>> f'i{LONG}'
iː
An implementation of the model "Distant to Local" from the following paper:
@article{belth2024tiers,
title={A Learning-Based Account of Phonological Tiers},
author={Belth, Caleb},
journal={Linguistic Inquiry},
year={2024},
publisher={MIT Press},
url = {https://doi.org/10.1162/ling\_a\_00530},
}
Please see the models README for details.
An implementation of the model "Meaning Informed Segmentation of Agglutinative Morphology" (Mɪᴀꜱᴇɢ) from the following paper:
@inproceedings{belth2024miaseg,
title={Meaning-Informed Low-Resource Segmentation of Agglutinative Morphology},
author={Belth, Caleb},
booktitle={Proceedings of the Society for Computation in Linguistics},
year={2024}
}
Please see the models README for details.
Work in Progress
If you use this package in your research, you can use the following citation:
@phdthesis{belth2023towards,
title={{Towards an Algorithmic Account of Phonological Rules and Representations}},
author={Belth, Caleb},
year={2023},
school={{University of Michigan}}
}
If you use one of the computational models, please cite the corresponding paper(s).
- Mortensen, D. R., Littell, P., Bharadwaj, A., Goyal, K., Dyer, C., & Levin, L. (2016, December). Panphon: A resource for mapping IPA segments to articulatory feature vectors. In Proceedings of COLING 2016, the 26th International Conference on Computational Linguistics: Technical Papers (pp. 3475-3484).