Library for computing Deterministic Acyclic Finite State Automata (DAFSA)
Project description
DAFSA
DAFSA is a library for computing Deterministic Acyclic Finite State Automata (also known as "directed acyclic word graphs", or DAWG). DAFSA are data structures derived from tries that allow to represent a set of sequences (typically character strings or n-grams) in the form of a directed acyclic graph with a single source vertex (the start
symbol of all sequences) and at least one sink edge (end
symbols, each pointed to by one or more sequences). In the current implementation, a trait of each node expresses whether it can be used a sink.
The primary difference between DAFSA and tries is that the latter eliminates suffix and infix redundancy, as in the example of Figure 1 (from the linked Wikipedia article) storing the set of strings "tap"
, "taps"
, "top"
, and "tops"
. Even though DAFSAs cannot be used to store precise frequency information, given that multiple paths can reach the same terminal node, they still allow to estimate the sampling frequency; being acyclic, they can also reject any sequence not included in the training. Fuzzy extensions will allow to estimate the sampling probability of unobserved sequences.
This data structure is a special case of a finite state recognizer that acts as a deterministic finite state automaton, as it recognizes all and only the sequences it was built upon. Frequently used in computer science for the space-efficient storage of sets of sequences without common compression techniques, such as dictionary or entropy types, or without probabilistic data structures, such as Bloom filters, the automata generated by this library are intended for linguistic exploration, and extend published models by allowing to approximate probability of random observation by carrying information on the weight of each graph edge.
Installation
In any standard Python environment, dafsa
can be installed with:
pip install dafsa
How to use
The library offers a DAFSA
object to compute automata, along with methods for checking a sequence acceptance and for exporting the graph. A minimal usage is shown here:
>>> import dafsa
>>> d = dafsa.DAFSA(["tap", "taps", "top", "tops", "dibs"])
>>> print(d)
DAFSA with 7 nodes and 8 edges (5 sequences)
+-- #0: 0(#1:<d>/1|#5:<t>/4) [('t', 5), ('d', 1)]
+-- #1: n(#2:<i>/1) [('i', 2)]
+-- #2: n(#3:<b>/1) [('b', 3)]
+-- #3: n(#4:<s>/3) [('s', 4)]
+-- #4: F() []
+-- #5: n(#6:<a>/2|#6:<o>/2) [('o', 6), ('a', 6)]
+-- #6: n(#3:<p>/4) [('p', 3)]
Note how the resulting graph includes the 5 training sequences, with one starting node (#0) that advances with either a t
(observed four times) or a d
symbol (observed a single time), a subsequent node to t
that only advances with a
and o
symbols (#1), and so on.
The visualization is much clearer with a graphical representation:
>>> d.graphviz_output("example.png")
A DAFSA object allows to check for the presence or absence of a sequence in its structure, returning a terminal node if it can find a path:
>>> d.lookup("tap")
F(#4:<s>/3)
>>> d.lookup("tops")
F()
>>> d.lookup("tapap") is None
True
>>> d.lookup("ta") is None
True
A command-line tool for reading files with lists of strings, with one string per line, is also available:
$ cat resources/dna.txt
CGCGAAA
CGCGATA
CGGAAA
CGGATA
GGATA
AATA
$ dafsa resources/dna.txt -t png -o dna.png
Which will produce the following graph:
Changelog
Version 0.2:
- Added support for weighted edges and nodes
- Added DOT export and Graphviz generation
- Refined minimization method, which can be skipped if desired (resulting in a standard trie)
- Added examples in the resources, also used for test data
Version 0.1:
- First public release.
Roadmap
Version 0.3:
- Add support for non-character tokens, allowing to use any Python iterable as long as its elements can be hashed
- Start integration with
networkx
, including:- Exporting DAFSA in standard network formats
- Computation of shortest or k-shortest paths, along with cumulative edge and/or node weights
- Preliminary generation of minimal regular expressions matching the contents of a DAFSA
- Allow to join attributes in single sub-paths
- Allow to replace final nodes with edges to
end-of-sequence
nodes (possibly as a default)
Version 0.4:
- Profile code and make faster and less resource hungry, using multiple threads wherever possible, memoization, etc.
- Work on options for nicer graphviz output (colors, widths, etc.)
- Decide how (and if) to implement a
.__gt__()
method for the nodes, both before and after the final minimization
Before 1.0:
- Add code from Daciuk's packages in an extra directory, along with notes on license
Please note that this library is under development and still needs performance optimizations: common experiments such as building a DAFSA for the contents of /usr/share/dict/words
will take many minutes in a common machine.
Alternatives
The main alternative to this library is the dawg
one, available at https://github.com/pytries/DAWG. dawg
wraps the dwagdic
C++ library, and is intended to production usage of DAFSAs as a space-efficient data structure. It does not support the computation of edge weights, nor it is intended for exporting the internal structure as a graph.
Other alternatives are the adfa
and minim
packages, written in C/C++, written by Jan Daciuk. The personal webpage hosting them has been offline for years, with a version at the Wayback Machine available. Note that the archived version does not include the packages.
How to cite
If you use dafsa
, please cite it as:
Tresoldi, Tiago (2019). DAFSA, a a library for computing Deterministic Acyclic Finite State Automata. Version 0.2. Jena. Available at: https://github.com/tresoldi/dafsa
In BibTeX:
@misc{Tresoldi2019dafsa,
author = {Tresoldi, Tiago},
title = {DAFSA, a a library for computing Deterministic Acyclic Finite State Automata. Version 0.2},
howpublished = {\url{https://github.com/tresoldi/dafsa}},
address = {Jena},
year = {2019},
}
References
Black, Paul E. and Pieterse, Vreda (eds.). 1998. "Directed acyclic word graph", Dictionary of Algorithms and Data Structures. Gaithersburg: National Institute of Standards and Technology.
Blumer, Anselm C.; Blumer, Janet A.; Haussler, David; Ehrenfeucht, Andrzej; Chen, M.T.; Seiferas, Joel I. 1985. "The smallest automaton recognizing the subwords of a text", Theoretical Computer Science, 40: 31–55. doi:10.1016/0304-3975(85)90157-4.
Ciura, Marcin G. and Deorowicz, Sebastian. 2002. "How to sequeeze a lexicon", Software-Practice and Experience 31(11):1077-1090.
Daciuk, Jan; Mihov, Stoyan; Watson, Bruce and Watson, Richard. 2000. "Incremental construction of minimal acyclic finite state automata." Computational Linguistics 26(1):3-16.
Havon, Steve. 2011. "Compressing dictionaries with a DAWG". Steve Hanov's Blog. url
Lucchesi, Cláudio L. and Kowaltowski, Tomasz. "Applications of finite automata representing large vocabularies". Software-Practice and Experience. 1993: 15–30. CiteSeerX 10.1.1.56.5272.
Author
Tiago Tresoldi (tresoldi@shh.mpg.de)
The author was supported during development by the ERC Grant #715618 for the project CALC (Computer-Assisted Language Comparison: Reconciling Computational and Classical Approaches in Historical Linguistics), led by Johann-Mattis List.
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