I'm trying to smooth a set of n-gram probabilities with Kneser-Ney smoothing using the Python NLTK. Unfortunately, the whole documentation is rather sparse.

What I'm trying to do is this: I parse a text into a list of tri-gram tuples. From this list I create a FreqDist and then use that FreqDist to calculate a KN-smoothed distribution.

I'm pretty sure though, that the result is totally wrong. When I sum up the individual probabilities I get something way beyond 1. Take this code example:

import nltk

ngrams = nltk.trigrams("What a piece of work is man! how noble in reason! how infinite in faculty! in \
form and moving how express and admirable! in action how like an angel! in apprehension how like a god! \
the beauty of the world, the paragon of animals!")

freq_dist = nltk.FreqDist(ngrams)
kneser_ney = nltk.KneserNeyProbDist(freq_dist)
prob_sum = 0
for i in kneser_ney.samples():
    prob_sum += kneser_ney.prob(i)

The output is "41.51696428571428". Depending on the corpus size, this value grows infinitely large. That makes whatever prob() returns anything but a probability distribution.

Looking at the NLTK code I would say that the implementation is questionable. Maybe I just don't understand how the code is supposed to be used. In that case, could you give me a hint please? In any other case: do you know any working Python implementation? I don't really want to implement it myself.

  • that's a log probability. So math.exp(41.51696428571428) = 1.0729722613480671e+18, very small probability. When it grows KN-smoothing grows larger, means the probability is smaller. But it might also be that the NLTK implementation is not right, please report issue to github.com/nltk/nltk/issues
    – alvas
    Commented Feb 7, 2016 at 10:23
  • I don't understand what you mean. 1.0729722613480671e+18 is not very small but in fact an extremely large number. 41.51696428571428 is the sum of all probabilities returned by KneserNeyProbDist and it should be around 1.0. Commented Feb 7, 2016 at 11:47
  • Whoop, misread the +/- on the e =) Report the issue in the github.
    – alvas
    Commented Feb 7, 2016 at 17:11

3 Answers 3


I think you are misunderstanding what Kneser-Ney is computing.

From Wikipedia:

The normalizing constant λwi-1 has value chosen carefully to make the sum of conditional probabilities pKN(wi|wi-1) equal to one.

Of course we're talking about bigrams here but the same principal is true for higher order models. Basically what this quote means is that, for a fixed context wi-1 (or more context for higher order models) the probabilities of all wi must add up to one. What you are doing when you add up the probabilities of all samples is including multiple contexts, which is why you end up with a "probability" greater than 1. If you keep the context fixed, as in the following code sample, you end up with a number <= 1.

    from nltk.util import ngrams
    from nltk.corpus import gutenberg

    gut_ngrams = ( ngram for sent in gutenberg.sents() for ngram in ngrams(sent, 3, pad_left = True, pad_right = True, right_pad_symbol='EOS', left_pad_symbol="BOS"))
    freq_dist = nltk.FreqDist(gut_ngrams)
    kneser_ney = nltk.KneserNeyProbDist(freq_dist)

    prob_sum = 0
    for i in kneser_ney.samples():
        if i[0] == "I" and i[1] == "confess":
            prob_sum += kneser_ney.prob(i)
            print "{0}:{1}".format(i, kneser_ney.prob(i))
    print prob_sum

The output, based on the NLTK Gutenberg corpus subset, is as follows.

    (u'I', u'confess', u'.--'):0.00657894736842
    (u'I', u'confess', u'what'):0.00657894736842
    (u'I', u'confess', u'myself'):0.00657894736842
    (u'I', u'confess', u'also'):0.00657894736842
    (u'I', u'confess', u'there'):0.00657894736842
    (u'I', u'confess', u',"'):0.0328947368421
    (u'I', u'confess', u'that'):0.164473684211
    (u'I', u'confess', u'"--'):0.00657894736842
    (u'I', u'confess', u'it'):0.0328947368421
    (u'I', u'confess', u';'):0.00657894736842
    (u'I', u'confess', u','):0.269736842105
    (u'I', u'confess', u'I'):0.164473684211
    (u'I', u'confess', u'unto'):0.00657894736842
    (u'I', u'confess', u'is'):0.00657894736842

The reason why this sum (.72) is less than 1 is that the probability is calculated only on trigrams appearing in the corpus where the first word is "I" and the second word is "confess." The remaining .28 probability is reserved for wis which do not follow "I" and "confess" in the corpus. This is the whole point of smoothing, to reallocate some probability mass from the ngrams appearing in the corpus to those that don't so that you don't end up with a bunch of 0 probability ngrams.

Also doesn't the line

    ngrams = nltk.trigrams("What a piece of work is man! how noble in reason! how infinite in faculty! in \
    form and moving how express and admirable! in action how like an angel! in apprehension how like a god! \
    the beauty of the world, the paragon of animals!")

compute character trigrams? I think this needs to be tokenized to compute word trigrams.


The Kneser-Ney (also have a look at Goodman and Chen for a great survey on different smoothing techniques) is a quite complicated smoothing which only a few package that I am aware of got it right. Not aware of any python implementation, but you can definitely try SRILM if you just need probabilities, etc.

  • There is a good chance that your sample has words that didn't occur in training data (aka Out-Of-Vocabulary (OOV) words), which if not handled properly can mess up the probabilities you get. Perhaps this can cause getting outrageously large and invalid prob?
  • 2
    Thanks for the answer. What I'm doing in the code above is simply adding the probabilities of all learned samples. So, I'm not checking probabilities of any unseen samples at all. Probabilities of unseen samples are handled strangely anyway. If i search for for an untrained (w1,w2,w3), then it checks if that one is known. If it is not, it gives a smoothed probability for (w2,w3). If that is unknown, too, it gives 0.0. So in almost all cases, you get 0.0 when checking unlearned trigrams which is absurd because I don't need smoothing for that. Commented Feb 8, 2016 at 14:06
  • @JanekBevendorff If you are "adding" probabilities, why is it unexpected to get a final probability which is above 1? Commented Feb 8, 2016 at 14:26
  • @JanekBevendorff and am putting this as another comment: to get the probability of your corpus, you shouldn't sum probabilities if they are not log-scaled. If they are log-scaled, then summation is fine. Note \log\product = \sum\log. Commented Feb 8, 2016 at 14:29
  • 1
    When I have a corpus of n-grams then their total summed probability should be one (+/- numerical errors). Otherwise my n-gram distribution is not a probability distribution. When I take that distribution and smooth it, then I want to redistribute the probabilities a little to account for sample-errors and make some space for "unseen" events. So when I sum over my smoothed probabilities, I expect a value of 1.0 - x where 0 <= x <= 1 is the portion for unseen n-grams. Commented Feb 8, 2016 at 17:07
  • 1
    @alvas that is not KN. It's modified KN of Goodman and Chen. KenLM doesn't have any smoothing beyond modified KN implemented. Commented Feb 8, 2016 at 22:38


In any other case: do you know any working Python implementation?

I just finished a Kneser-Ney implementation in Python. The code is here; there are reports in the README also. Write me for any doubts.

  • While this link may answer the question, it is better to include the essential parts of the answer here and provide the link for reference. Link-only answers can become invalid if the linked page changes. - From Review
    – Andy
    Commented Feb 20, 2016 at 3:36
  • I was just answering to the question "do you know any working Python implementation?" Commented Feb 20, 2016 at 23:20
  • Except for iterating over 0-gram, but doing nothing with them, and for keeping a map of sets of previous words and next words, while the size of the set is the only thing of interest after training, this code seems descent enough. Thanks for sharing. Commented Jul 14, 2016 at 17:41
  • Also, it would seem you ignore the provided discount parameter... if none is given you search for the one which minimizes perplexity, but if one is given you don't use it.. you instead use some ad-hoc method of calculating it which is different than the one you use if none is given... This seems odd. Commented Jul 14, 2016 at 19:44
  • @Mr.WorshipMe Regarding to the discount parameter, you are right, the documentation is not quite correct. Actually, the parameter D is a flag: if it is set to None (default), D will be computed as in the paper from where I took the algorithm. If it is not None, the algorithm will try a few values and use the one that gives better results. That said, the discount parameter answers the question "Would you like to compute D or just try different values and choose the better one?". Thank you for the comment, I will modify the script to avoid this kind of confusion. Commented Jul 15, 2016 at 18:39

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