I want to get this:
Input text: "ру́сский язы́к"
Output text: "Russian"
Input text: "中文"
Output text: "Chinese"
Input text: "にほんご"
Output text: "Japanese"
Input text: "العَرَبِيَّة"
Output text: "Arabic"
How can I do it in python?
I want to get this:
Input text: "ру́сский язы́к"
Output text: "Russian"
Input text: "中文"
Output text: "Chinese"
Input text: "にほんご"
Output text: "Japanese"
Input text: "العَرَبِيَّة"
Output text: "Arabic"
How can I do it in python?
Requires NLTK package, uses Google.
from textblob import TextBlob
b = TextBlob("bonjour")
b.detect_language()
pip install textblob
Note: This solution requires internet access and Textblob is using Google Translate's language detector by calling the API.
Requires numpy and some arcane libraries, unlikely to get it work for Windows. (For Windows, get an appropriate versions of PyICU, Morfessor and PyCLD2 from here, then just pip install downloaded_wheel.whl
.) Able to detect texts with mixed languages.
from polyglot.detect import Detector
mixed_text = u"""
China (simplified Chinese: 中国; traditional Chinese: 中國),
officially the People's Republic of China (PRC), is a sovereign state
located in East Asia.
"""
for language in Detector(mixed_text).languages:
print(language)
# name: English code: en confidence: 87.0 read bytes: 1154
# name: Chinese code: zh_Hant confidence: 5.0 read bytes: 1755
# name: un code: un confidence: 0.0 read bytes: 0
pip install polyglot
To install the dependencies, run:
sudo apt-get install python-numpy libicu-dev
Note: Polyglot is using pycld2
, see https://github.com/aboSamoor/polyglot/blob/master/polyglot/detect/base.py#L72 for details.
Chardet has also a feature of detecting languages if there are character bytes in range (127-255]:
>>> chardet.detect("Я люблю вкусные пампушки".encode('cp1251'))
{'encoding': 'windows-1251', 'confidence': 0.9637267119204621, 'language': 'Russian'}
pip install chardet
Requires large portions of text. It uses non-deterministic approach under the hood. That means you get different results for the same text sample. Docs say you have to use following code to make it determined:
from langdetect import detect, DetectorFactory
DetectorFactory.seed = 0
detect('今一はお前さん')
pip install langdetect
Can detect very short samples by using this spell checker with dictionaries.
pip install guess_language-spirit
langid.py provides both a module
import langid
langid.classify("This is a test")
# ('en', -54.41310358047485)
and a command-line tool:
$ langid < README.md
pip install langid
FastText is a text classifier, can be used to recognize 176 languages with a proper models for language classification. Download this model, then:
import fasttext
model = fasttext.load_model('lid.176.ftz')
print(model.predict('الشمس تشرق', k=2)) # top 2 matching languages
(('__label__ar', '__label__fa'), array([0.98124713, 0.01265871]))
pip install fasttext
pycld3 is a neural network model for language identification. This package contains the inference code and a trained model.
import cld3
cld3.get_language("影響包含對氣候的變化以及自然資源的枯竭程度")
LanguagePrediction(language='zh', probability=0.999969482421875, is_reliable=True, proportion=1.0)
pip install pycld3
polyglot
ended up being the most performant for my use case. langid
came in second
Commented
Feb 23, 2019 at 13:19
Have you had a look at langdetect?
from langdetect import detect
lang = detect("Ein, zwei, drei, vier")
print lang
#output: de
ro
(Romanian). Multiple language output required for such cases. polyglot performs much better.
Commented
Jun 20, 2018 at 10:41
langdetect
can determine different languages :-)
Commented
Jun 27, 2018 at 10:12
@Rabash had a good list of tools on https://stackoverflow.com/a/47106810/610569
And @toto_tico did a nice job in presenting the speed comparison.
Here's a summary to complete the great answers above (as of 2021)
Language ID software | Used by | Open Source / Model | Rule-based | Stats-based | Can train/tune |
---|---|---|---|---|---|
Google Translate Language Detection | TextBlob (limited usage) | ✕ | - | - | ✕ |
Chardet | - | ✓ | ✓ | ✕ | ✕ |
Guess Language (non-active development) | spirit-guess (updated rewrite) | ✓ | ✓ | Minimally | ✕ |
pyCLD2 | Polyglot | ✓ | Somewhat | ✓ | Not sure |
CLD3 | - | ✓ | ✕ | ✓ | Possibly |
langid-py | - | ✓ | Not sure | ✓ | ✓ |
langdetect | SpaCy-langdetect | ✓ | ✕ | ✓ | ✓ |
FastText | What The Lang | ✓ | ✕ | ✓ | Not sure |
If you are looking for a library that is fast with long texts, polyglot
and fastext
are doing the best job here.
I sampled 10000 documents from a collection of dirty and random HTMLs, and here are the results:
+------------+----------+
| Library | Time |
+------------+----------+
| polyglot | 3.67 s |
+------------+----------+
| fasttext | 6.41 |
+------------+----------+
| cld3 | 14 s |
+------------+----------+
| langid | 1min 8s |
+------------+----------+
| langdetect | 2min 53s |
+------------+----------+
| chardet | 4min 36s |
+------------+----------+
I have noticed that a lot of the methods focus on short texts, probably because it is the hard problem to solve: if you have a lot of text, it is really easy to detect languages (e.g. one could just use a dictionary!). However, this makes it difficult to find for an easy and suitable method for long texts.
polyglot
language detection is based on pycld2
, that is not that fast all in all. Or is there a way to use it to identify the language in a kind of a batch mode? I have only tried handling sentence by sentence.
Commented
Jun 5, 2020 at 13:30
\n
characters, but not for polyglot (cdl2 results were pretty much the same, I tested it as well). I don't understand why you think polyglot is slow, It was the fastest. Do you think I should have removed the \n
as well, and that my results just reflect the first sentence (i.e., before the first \n
)
Commented
Jun 6, 2020 at 15:57
There is an issue with langdetect
when it is being used for parallelization and it fails. But spacy_langdetect
is a wrapper for that and you can use it for that purpose. You can use the following snippet as well:
import spacy
from spacy_langdetect import LanguageDetector
nlp = spacy.load("en")
nlp.add_pipe(LanguageDetector(), name="language_detector", last=True)
text = "This is English text Er lebt mit seinen Eltern und seiner Schwester in Berlin. Yo me divierto todos los días en el parque. Je m'appelle Angélica Summer, j'ai 12 ans et je suis canadienne."
doc = nlp(text)
# document level language detection. Think of it like average language of document!
print(doc._.language['language'])
# sentence level language detection
for i, sent in enumerate(doc.sents):
print(sent, sent._.language)
langdetect
. I have a DF column with texts, I am using column.apply()
with a function doing scipy_langdetect
. Any suggestions?
Commented
Mar 31, 2020 at 15:04
dask
, otherwise it wouldn't make any difference.
Commented
Mar 31, 2020 at 22:40
langdetect
library for dask
parallelization it threw an exception but spacy_langdetect
worked fine.
Commented
Jun 30, 2021 at 19:26
You can use Googletrans (unofficial) a free and unlimited Google translate API for Python.
You can make as many requests as you want, there are no limits
Installation:
$ pip install googletrans
Language detection:
>>> from googletrans import Translator
>>> t = Translator().detect("hello world!")
>>> t.lang
'en'
>>> t.confidence
0.8225234
I would say lingua.py all the way. It is much faster and more accurate than fasttext
. Definitely deserves to be listed here.
poetry add lingua-language-detector
from typing import List
from lingua.language import Language
from lingua.builder import LanguageDetectorBuilder
languages: List[Language] = [Language.ENGLISH, Language.TURKISH, Language.PERSIAN]
detector = LanguageDetectorBuilder.from_languages(*languages).build()
if __name__ == "__main__":
print(detector.detect_language_of("Ben de iyiyim. Tesekkurler.")) # Language.TURKISH
print(detector.detect_language_of("I'm fine and you?")) # Language.ENGLISH
print(detector.detect_language_of("حال من خوبه؟ شما چطورید؟")) # Language.PERSIAN
I arrived at your question with a very similar need. I found the most help from Rabash's answers for my specific needs.
After experimenting to find what worked best among his recommendations, which was making sure that text files were in English in 60,000+ text files, I found that fasttext was an excellent tool for such a task.
With a little work, I had a tool that worked very fast over many files. But it could be easily modified for something like your case, because fasttext works over a list of lines easily.
My code with comments is among the answers on THIS post. I believe that you and others can easily modify this code for other specific needs.
Depending on the case, you might be interested in using one of the following methods:
Method 0: Use an API or library
Usually, there are a few problems with these libraries because some of them are not accurate for small texts, some languages are missing, are slow, require internet connection, are non-free,... But generally speaking, they will suit most needs.
Method 1: Language models
A language model gives us the probability of a sequence of words. This is important because it allows us to robustly detect the language of a text, even when the text contains words in other languages (e.g.: "'Hola' means 'hello' in spanish").
You can use N language models (one per language), to score your text. The detected language will be the language of the model that gave you the highest score.
If you want to build a simple language model for this, I'd go for 1-grams. To do this, you only need to count the number of times each word from a big text (e.g. Wikipedia Corpus in "X" language) has appeared.
Then, the probability of a word will be its frequency divided by the total number of words analyzed (sum of all frequencies).
the 23135851162
of 13151942776
and 12997637966
to 12136980858
a 9081174698
in 8469404971
for 5933321709
...
=> P("'Hola' means 'hello' in spanish") = P("hola") * P("means") * P("hello") * P("in") * P("spanish")
If the text to detect is quite big, I recommend sampling N random words and then use the sum of logarithms instead of multiplications to avoid floating-point precision problems.
P(s) = 0.03 * 0.01 * 0.014 = 0.0000042
P(s) = log10(0.03) + log10(0.01) + log10(0.014) = -5.376
Method 2: Intersecting sets
An even simpler approach is to prepare N sets (one per language) with the top M most frequent words. Then intersect your text with each set. The set with the highest number of intersections will be your detected language.
spanish_set = {"de", "hola", "la", "casa",...}
english_set = {"of", "hello", "the", "house",...}
czech_set = {"z", "ahoj", "závěrky", "dům",...}
...
text_set = {"hola", "means", "hello", "in", "spanish"}
spanish_votes = text_set.intersection(spanish_set) # 1
english_votes = text_set.intersection(english_set) # 4
czech_votes = text_set.intersection(czech_set) # 0
...
Method 3: Zip compression
This more a curiosity than anything else, but here it goes... You can compress your text (e.g LZ77) and then measure the zip-distance with regards to a reference compressed text (target language). Personally, I didn't like it because it's slower, less accurate and less descriptive than other methods. Nevertheless, there might be interesting applications for this method. To read more: Language Trees and Zipping
I have tried all the libraries out there, and i concluded that pycld2 is the best one, fast and accurate.
you can install it like this:
python -m pip install -U pycld2
you can use it like this:
isReliable, textBytesFound, details = cld2.detect(your_sentence)
print(isReliable, details[0][1]) # reliablity(bool),lang abbrev.(en/es/de...)
Polygot or Cld2 are among the best suggestions because they can detect multiple language in text. But, they are not easy to be installed on Windows because of "building wheel fail".
A solution that worked for me ( I am using Windows 10 ) is installing CLD2-CFFI
so first install cld2-cffi
pip install cld2-cffi
and then use it like this:
text_content = """ A accès aux chiens et aux frontaux qui lui ont été il peut
consulter et modifier ses collections et exporter Cet article concerne le pays
européen aujourd’hui appelé République française.
Pour d’autres usages du nom France, Pour une aide rapide et effective, veuiller
trouver votre aide dans le menu ci-dessus.
Welcome, to this world of Data Scientist. Today is a lovely day."""
import cld2
isReliable, textBytesFound, details = cld2.detect(text_content)
print(' reliable: %s' % (isReliable != 0))
print(' textBytes: %s' % textBytesFound)
print(' details: %s' % str(details))
Th output is like this:
reliable: True
textBytes: 377
details: (Detection(language_name='FRENCH', language_code='fr', percent=74,
score=1360.0), Detection(language_name='ENGLISH', language_code='en',
percent=25, score=1141.0), Detection(language_name='Unknown',
language_code='un', percent=0, score=0.0))
I like the approach offered by TextBlob for language detection. Its quite simple and easy to implement and uses fewer lines of code. before you begin. you will need to install the textblob python library for the below code to work.
from textblob import TextBlob
text = "это компьютерный портал для гиков."
lang = TextBlob(text)
print(lang.detect_language())
On the other hand, if you have a combination of various languages used, you might want to try pycld2 that allows language detection by defining parts of the sentence or paragraph with accuracy.
You can try determining the Unicode group of chars in input string to point out type of language, (Cyrillic for Russian, for example), and then search for language-specific symbols in text.
If the language you want to detect is among these...
...then it is relatively easy with HuggingFace libraries and models (Deep Learning Natural Language Processing, if you are not familiar with it):
# Import libraries
from transformers import pipeline
# Load pipeline
classifier = pipeline("text-classification", model = "papluca/xlm-roberta-base-language-detection")
# Example sentence
sentence1 = 'Ciao, come stai?'
# Get language
classifier(sentence1)
Output:
[{'label': 'it', 'score': 0.9948362112045288}]
label
is the predicted language, and score
is the assigned score to it: you can think of it as a confidence measure.
Some details:
The training set contains 70k samples, while the validation and test sets 10k each. The average accuracy on the test set is 99.6%
You can finde more info at the model's page, and I suppose that you could find other models that fit you needs.
You can install the pycld2
python library
pip install pycld2
or
python -m pip install -U pycld2
for the below code to work.
import pycld2 as cld2
isReliable, textBytesFound, details = cld2.detect(
"а неправильный формат идентификатора дн назад"
)
print(isReliable)
# True
details[0]
# ('RUSSIAN', 'ru', 98, 404.0)
fr_en_Latn = """\
France is the largest country in Western Europe and the third-largest in Europe as a whole.
A accès aux chiens et aux frontaux qui lui ont été il peut consulter et modifier ses collections
et exporter Cet article concerne le pays européen aujourd’hui appelé République française.
Pour d’autres usages du nom France, Pour une aide rapide et effective, veuiller trouver votre aide
dans le menu ci-dessus.
Motoring events began soon after the construction of the first successful gasoline-fueled automobiles.
The quick brown fox jumped over the lazy dog."""
isReliable, textBytesFound, details, vectors = cld2.detect(
fr_en_Latn, returnVectors=True
)
print(vectors)
# ((0, 94, 'ENGLISH', 'en'), (94, 329, 'FRENCH', 'fr'), (423, 139, 'ENGLISH', 'en'))
Pycld2 python library is a python binding for the Compact Language Detect 2 (CLD2). You can explore the different functionality of Pycld2. Know about the Pycld2 here.
The best way to determine the laguage of a text is to implement the following function:
from langdetect import detect
def get_language(text):
keys =['ab', 'aa', 'af', 'ak', 'sq', 'am', 'ar', 'an', 'hy', 'as', 'av', 'ae', 'ay', 'az', 'bm', 'ba', 'eu', 'be', 'bn', 'bi', 'bs', 'br', 'bg', 'my', 'ca', 'ch', 'ce', 'ny', 'zh', 'cu', 'cv', 'kw', 'co', 'cr', 'hr', 'cs', 'da', 'dv', 'nl', 'dz', 'en', 'eo', 'et', 'ee', 'fo', 'fj', 'fi', 'fr', 'fy', 'ff', 'gd', 'gl', 'lg', 'ka', 'de', 'el', 'kl', 'gn', 'gu', 'ht', 'ha', 'he', 'hz', 'hi', 'ho', 'hu', 'is', 'io', 'ig', 'id', 'ia', 'ie', 'iu', 'ik', 'ga', 'it', 'ja', 'jv', 'kn', 'kr', 'ks', 'kk', 'km', 'ki', 'rw', 'ky', 'kv', 'kg', 'ko', 'kj', 'ku', 'lo', 'la', 'lv', 'li', 'ln', 'lt', 'lu', 'lb', 'mk', 'mg', 'ms', 'ml', 'mt', 'gv', 'mi', 'mr', 'mh', 'mn', 'na', 'nv', 'nd', 'nr', 'ng', 'ne', 'no', 'nb', 'nn', 'ii', 'oc', 'oj', 'or', 'om', 'os', 'pi', 'ps', 'fa', 'pl', 'pt', 'pa', 'qu', 'ro', 'rm', 'rn', 'ru', 'se', 'sm', 'sg', 'sa', 'sc', 'sr', 'sn', 'sd', 'si', 'sk', 'sl', 'so', 'st', 'es', 'su', 'sw', 'ss', 'sv', 'tl', 'ty', 'tg', 'ta', 'tt', 'te', 'th', 'bo', 'ti', 'to', 'ts', 'tn', 'tr', 'tk', 'tw', 'ug', 'uk', 'ur', 'uz', 've', 'vi', 'vo', 'wa', 'cy', 'wo', 'xh', 'yi', 'yo', 'za', 'zu']
langs = ['Abkhazian', 'Afar', 'Afrikaans', 'Akan', 'Albanian', 'Amharic', 'Arabic', 'Aragonese', 'Armenian', 'Assamese', 'Avaric', 'Avestan', 'Aymara', 'Azerbaijani', 'Bambara', 'Bashkir', 'Basque', 'Belarusian', 'Bengali', 'Bislama', 'Bosnian', 'Breton', 'Bulgarian', 'Burmese', 'Catalan, Valencian', 'Chamorro', 'Chechen', 'Chichewa, Chewa, Nyanja', 'Chinese', 'Church Slavonic, Old Slavonic, Old Church Slavonic', 'Chuvash', 'Cornish', 'Corsican', 'Cree', 'Croatian', 'Czech', 'Danish', 'Divehi, Dhivehi, Maldivian', 'Dutch, Flemish', 'Dzongkha', 'English', 'Esperanto', 'Estonian', 'Ewe', 'Faroese', 'Fijian', 'Finnish', 'French', 'Western Frisian', 'Fulah', 'Gaelic, Scottish Gaelic', 'Galician', 'Ganda', 'Georgian', 'German', 'Greek, Modern (1453–)', 'Kalaallisut, Greenlandic', 'Guarani', 'Gujarati', 'Haitian, Haitian Creole', 'Hausa', 'Hebrew', 'Herero', 'Hindi', 'Hiri Motu', 'Hungarian', 'Icelandic', 'Ido', 'Igbo', 'Indonesian', 'Interlingua (International Auxiliary Language Association)', 'Interlingue, Occidental', 'Inuktitut', 'Inupiaq', 'Irish', 'Italian', 'Japanese', 'Javanese', 'Kannada', 'Kanuri', 'Kashmiri', 'Kazakh', 'Central Khmer', 'Kikuyu, Gikuyu', 'Kinyarwanda', 'Kirghiz, Kyrgyz', 'Komi', 'Kongo', 'Korean', 'Kuanyama, Kwanyama', 'Kurdish', 'Lao', 'Latin', 'Latvian', 'Limburgan, Limburger, Limburgish', 'Lingala', 'Lithuanian', 'Luba-Katanga', 'Luxembourgish, Letzeburgesch', 'Macedonian', 'Malagasy', 'Malay', 'Malayalam', 'Maltese', 'Manx', 'Maori', 'Marathi', 'Marshallese', 'Mongolian', 'Nauru', 'Navajo, Navaho', 'North Ndebele', 'South Ndebele', 'Ndonga', 'Nepali', 'Norwegian', 'Norwegian Bokmål', 'Norwegian Nynorsk', 'Sichuan Yi, Nuosu', 'Occitan', 'Ojibwa', 'Oriya', 'Oromo', 'Ossetian, Ossetic', 'Pali', 'Pashto, Pushto', 'Persian', 'Polish', 'Portuguese', 'Punjabi, Panjabi', 'Quechua', 'Romanian, Moldavian, Moldovan', 'Romansh', 'Rundi', 'Russian', 'Northern Sami', 'Samoan', 'Sango', 'Sanskrit', 'Sardinian', 'Serbian', 'Shona', 'Sindhi', 'Sinhala, Sinhalese', 'Slovak', 'Slovenian', 'Somali', 'Southern Sotho', 'Spanish, Castilian', 'Sundanese', 'Swahili', 'Swati', 'Swedish', 'Tagalog', 'Tahitian', 'Tajik', 'Tamil', 'Tatar', 'Telugu', 'Thai', 'Tibetan', 'Tigrinya', 'Tonga (Tonga Islands)', 'Tsonga', 'Tswana', 'Turkish', 'Turkmen', 'Twi', 'Uighur, Uyghur', 'Ukrainian', 'Urdu', 'Uzbek', 'Venda', 'Vietnamese', 'Volapük', 'Walloon', 'Welsh', 'Wolof', 'Xhosa', 'Yiddish', 'Yoruba', 'Zhuang, Chuang', 'Zulu']
lang_dict = {key : lan for (key, lan) in zip(keys, langs)}
return lang_dict[detect(text)]
Let's try it:
>>> get_language("Ich liebe meine Frau")
... 'German'