# Release nlp (londogard-nlp-toolkit) 1.1.0

The 1.1.0 release of nlp (londogard-nlp-toolkit) by londogard is finally here!

I’m writing this small blog-post mainly to showcase some of the new things possible now that we’re moving into classifer-space!
This release took some time to complete because there was some big restructuring and custom implementations required. One thing that I wasn't expecting was to implement my own Sparse Matrix on top of multik because there's currently no support. Without sparsity text features will make your memory dissapear before you take your second breath! 😅
Luckily I managed to get something up and running. The code is now cleaner and more efficient than previously on top of all the new features.

N.B.
Most of the examples are taken from /src/test.

# Vectorizers

The first part I'd like to present is the tooling that required sparse matrices, vectorizers. TF-IDF, Bag of Words & BM-25 requires huge matrices that are very sparse, having it all in memory would be crazy as > 90% is empty (=0.0).
Let's look at the vectorizers that now exists:

1. Bag of Words, also called Count Vectorizer in sklearn.

• This vectorizer takes words and assign a unique number to each, which is then filled in the final vector
2. TF-IDF

• This vectorizer assigns values to word based on their term frequency & inverse-document frequency. Which is a incredible strong baseline. (Wikipedia.org)
3. BM-25

• This vectorizer is a improvement on top of TF-IDF used by Elastic Search among others. The difference is that BM-25 also base the magnitude on the sentences length, in TF-IDF sometimes long sentences tend to get very high magnitude. (Wikipedia)

And yes, it’s possible to vectorize with ngrams! 🥳
And yes (x2), it’s using Sparse Matrices to keep performance at top! 🤩

All in all this puts us very close to the famous sklearn in terms of versatility.

### Usage of Vectorizers​

val simpleTok = SimpleTokenizer()  val simpleTexts = listOf("hello world!", "this is a few sentences")      .map(simpleTok::split)  val tfidf = TfIdfVectorizer<Float>() // replace by CountVectorizer or Bm25Vectorizer    val lhs = tfidf.fitTransform(simpleTexts)  println("Vectorized: \$lhs")

## Classifiers​

And the first feature built on top of the new vectors... classifiers!
To be able to figure out if a tweet is negative or positive we need to classify the text, based on the vectorized data.
The following classifiers are added for now:

• Logistic Regression using Stochastic Gradient Descent as optimizer
• Naïve Bayes classifier
• Hidden Markov Model to classify sequences with a sequence output, e.g. Part of Speech (PoS) or Named Entitiy Recognition (NER).

### Usage of Classifiers​

val tfidf = TfIdfVectorizer<Float>()  val naiveBayes = NaiveBayes() // replace by LogisticRegression if needed    val out = tfidf.fitTransform(simpleTexts)  naiveBayes.fit(out, y)    naiveBayes.predict(out) shouldBeEqualTo y

and for sequences:

val (tokensText, tagsText) = text      .split('\\n')      .map {          val (a, b) = it.split('\\t')          a to b      }.unzip()  val tokenMap = (tokensText).toSet().withIndex().associate { elem -> elem.value to elem.index }  val tagMap = (tagsText + "BOS").toSet().withIndex().associate { elem -> elem.value to elem.index }  val reversetagMap = tagMap.asIterable().associate { (key, value) -> value to key }  val hmm = HiddenMarkovModel(      tagMap.asIterable().associate { (key, value) -> value to key },      tokenMap.asIterable().associate { (key, value) -> value to key },      BegginingOfSentence = tokenMap.getOrDefault("BOS", 0)      )    val x = listOf(mk.ndarray(tokensText.mapNotNull(tokenMap::get).toIntArray()))  val y = listOf(mk.ndarray(tagsText.mapNotNull(tagMap::get).toIntArray()))      hmm.fit(x, y)  // predict.map { t -> t.data.map { reversetagMap$it$ } } to get the real labels!  hmm.predict(x) shouldBeEqualTo y

## Unsupervised Keyword Extraction​

I couldn't keep my release small enough... so I added a little gem, automatic keyword extraction! This tool is very fast and efficient at doing what it’s doing and is based on a Co-Occurrence Statistical Information algorithm proposed by Y. Matsuo & M. Ishizuka in the following paper.
I think this is incredibly useful when you need something fast, cheap and that takes you 90% of the way!

### Usage of Keyword Extraction​

val keywords = CooccurrenceKeywords.keywords("Londogard NLP toolkit is works on multiple languages.\\nAn amazing piece of NLP tech.\\nThis is how to fetch keywords! ")    keywords shouldBeEqualTo listOf(listOf("nlp") to 2)

## Embedding Improvements​

LightWordEmbeddings  have had their cache updated into a optimal cache by caffeine , which instead of being randomly deleted from cache takes the least used and remove. This will improve performance greatly!

That’s it, I’m hoping to release a spaCy-like API during 2022, including Neural Networks. Here’s to the future! 🍾