PolyFuzz performs fuzzy string matching, grouping, and evaluation.
PolyFuzz
performs fuzzy string matching, string grouping, and contains extensive evaluation functions.
PolyFuzz is meant to bring fuzzy string matching techniques together within a single framework.
Currently, methods include a variety of edit distance measures, a character-based n-gram TF-IDF, word embedding techniques such as FastText and GloVe, and 🤗 transformers embeddings.
Corresponding medium post can be found here.
You can install PolyFuzz
via pip:
pip install polyfuzz
You may want to install more depending on the transformers and language backends that you will be using. The possible installations are:
pip install polyfuzz[sbert]
pip install polyfuzz[flair]
pip install polyfuzz[gensim]
pip install polyfuzz[spacy]
pip install polyfuzz[use]
If you want to speed up the cosine similarity comparison and decrease memory usage when using embedding models,
you can use sparse_dot_topn
which is installed via:
pip install polyfuzz[fast]
You might run into installation issues with sparse_dot_topn
. If so, one solution that has worked for many
is by installing it via conda first before installing PolyFuzz:
conda install -c conda-forge sparse_dot_topn
If that does not work, I would advise you to look through their
issues](https://github.com/ing-bank/sparse_dot_topn/issues) page or continue to use PolyFuzz without sparse_dot_topn
.
For an in-depth overview of the possibilities of PolyFuzz
you can check the full documentation here or you can follow along
with the notebook here.
The main goal of PolyFuzz
is to allow the user to perform different methods for matching strings.
We start by defining two lists, one to map from and one to map to. We are going to be using TF-IDF
to create
n-grams on a character level in order to compare similarity between strings. Then, we calculate the similarity
between strings by calculating the cosine similarity between vector representations.
We only have to instantiate PolyFuzz
with TF-IDF
and match the lists:
from polyfuzz import PolyFuzz
from_list = ["apple", "apples", "appl", "recal", "house", "similarity"]
to_list = ["apple", "apples", "mouse"]
model = PolyFuzz("TF-IDF")
model.match(from_list, to_list)
The resulting matches can be accessed through model.get_matches()
:
>>> model.get_matches()
From To Similarity
0 apple apple 1.000000
1 apples apples 1.000000
2 appl apple 0.783751
3 recal None 0.000000
4 house mouse 0.587927
5 similarity None 0.000000
NOTE 1: If you want to compare distances within a single list, you can simply pass that list as such: model.match(from_list)
NOTE 2: When instantiating PolyFuzz
we also could have used "EditDistance" or "Embeddings" to quickly
access Levenshtein and FastText (English) respectively.
The .match
function allows you to quickly extract similar strings. However, after selecting the right models to be used, you may want to use PolyFuzz
in production to match incoming strings. To do so, we can make use of the familiar fit
, transform
, and fit_transform
functions.
Let's say that we have a list of words that we know to be correct called train_words
. We want to any incoming word to mapped to one of the words in train_words
.
In other words, we fit
on train_words
and we use transform
on any incoming words:
from sklearn.datasets import fetch_20newsgroups
from sklearn.feature_extraction.text import CountVectorizer
from polyfuzz import PolyFuzz
train_words = ["apple", "apples", "appl", "recal", "house", "similarity"]
unseen_words = ["apple", "apples", "mouse"]
# Fit
model = PolyFuzz("TF-IDF")
model.fit(train_words)
# Transform
results = model.transform(unseen_words)
In the above example, we are using fit
on train_words
to calculate the TF-IDF representation of those words which are saved to be used again in transform
.
This speeds up transform
quite a bit since all TF-IDF representations are stored when applying fit
.
Then, we apply save and load the model as follows to be used in production:
# Save the model
model.save("my_model")
# Load the model
loaded_model = PolyFuzz.load("my_model")
We can group the matches To
as there might be significant overlap in strings in our to_list.
To do this, we calculate the similarity within strings in to_list and use single linkage
to then
group the strings with a high similarity.
When we extract the new matches, we can see an additional column Group
in which all the To
matches were grouped to:
>>> model.group(link_min_similarity=0.75)
>>> model.get_matches()
From To Similarity Group
0 apple apple 1.000000 apples
1 apples apples 1.000000 apples
2 appl apple 0.783751 apples
3 recal None 0.000000 None
4 house mouse 0.587927 mouse
5 similarity None 0.000000 None
As can be seen above, we grouped apple and apples together to apple
such that when a string is mapped to apple
it
will fall in the cluster of [apples, apple]
and will be mapped to the first instance in the cluster which is apples
.
Next, we would like to see how well our model is doing on our data. We express our results as
precision
and recall
where precision is defined as the minimum similarity score before a match is correct and
recall the percentage of matches found at a certain minimum similarity score.
Creating the visualizations is as simple as:
model.visualize_precision_recall()
Currently, the following models are implemented in PolyFuzz:
With Flair
, we can use all 🤗 Transformers models.
We simply have to instantiate any Flair WordEmbedding method and pass it through PolyFuzzy.
All models listed above can be found in polyfuzz.models
and can be used to create and compare different models:
from polyfuzz.models import EditDistance, TFIDF, Embeddings
from flair.embeddings import TransformerWordEmbeddings
embeddings = TransformerWordEmbeddings('bert-base-multilingual-cased')
bert = Embeddings(embeddings, min_similarity=0, model_id="BERT")
tfidf = TFIDF(min_similarity=0)
edit = EditDistance()
string_models = [bert, tfidf, edit]
model = PolyFuzz(string_models)
model.match(from_list, to_list)
To access the results, we again can call get_matches
but since we have multiple models we get back a dictionary
of dataframes back.
In order to access the results of a specific model, call get_matches
with the correct id:
>>> model.get_matches("BERT")
From To Similarity
0 apple apple 1.000000
1 apples apples 1.000000
2 appl apple 0.928045
3 recal apples 0.825268
4 house mouse 0.887524
5 similarity mouse 0.791548
Finally, visualize the results to compare the models:
model.visualize_precision_recall(kde=True)
We can even use one of the polyfuzz.models
to be used as the grouper in case you would like to use
something else than the standard TF-IDF model:
model = PolyFuzz("TF-IDF")
model.match(from_list, to_list)
edit_grouper = EditDistance(n_jobs=1)
model.group(edit_grouper)
Although the options above are a great solution for comparing different models, what if you have developed your own?
If you follow the structure of PolyFuzz's BaseMatcher
you can quickly implement any model you would like.
Below, we are implementing the ratio similarity measure from RapidFuzz.
import numpy as np
import pandas as pd
from rapidfuzz import fuzz
from polyfuzz.models import BaseMatcher
class MyModel(BaseMatcher):
def match(self, from_list, to_list, **kwargs):
# Calculate distances
matches = [[fuzz.ratio(from_string, to_string) / 100 for to_string in to_list]
for from_string in from_list]
# Get best matches
mappings = [to_list[index] for index in np.argmax(matches, axis=1)]
scores = np.max(matches, axis=1)
# Prepare dataframe
matches = pd.DataFrame({'From': from_list,'To': mappings, 'Similarity': scores})
return matches
Then, we can simply create an instance of MyModel and pass it through PolyFuzz:
custom_model = MyModel()
model = PolyFuzz(custom_model)
To cite PolyFuzz in your work, please use the following bibtex reference:
@misc{grootendorst2020polyfuzz,
author = {Maarten Grootendorst},
title = {PolyFuzz: Fuzzy string matching, grouping, and evaluation.},
year = 2020,
publisher = {Zenodo},
version = {v0.2.2},
doi = {10.5281/zenodo.4461050},
url = {https://doi.org/10.5281/zenodo.4461050}
}
Below, you can find several resources that were used for or inspired by when developing PolyFuzz:
Edit distance algorithms:
These algorithms focus primarily on edit distance measures and can be used in polyfuzz.models.EditDistance
:
Other interesting repos: