Metadata-Version: 2.1
Name: snlp
Version: 0.1.3.post3
Summary: Statistical NLP
Home-page: https://github.com/meghdadFar/snlp
Author: meghdadFar
Author-email: meghdad.farahmand@gmail.com
License: UNKNOWN
Description: # snlp
        
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        Statistical NLP (SNLP) is a practical package with statistical tools for natural language processing. SNLP is based on statistical and distributional attributes of natural language and hence most of its functionalities are unsupervised. 
        
        # Features
        - [Text Analysis](#text-analysis)
        - [Extraction of Multiword Expressions](#extraction-of-multiword-expressions)
        - [Identification of Statistically Redundant Words](#identification-of-statistically-redundant-words)
        - [Text Cleaning](#text-cleaning)
        
        ## Upcoming Features
        - **Identification of Non-compositional Expressions (e.g. *red tape* and *brain drain*)**. Non-compositional expressions have application in profanity detection, language understanding, and language generation.
        
        - **Entropy for Natural Language** Entropy has a wide range of applications in NLP. Recently, researchers have show that it can be used to improve the quality of conversational AI [[1]](#1) and text summarization [[2]](#2).
        
        - **Label Evaluation** Labeled datasets often come with certain level of human error. If not captured early on, this these errors will propagate to downstream machine learning models and hinder their quality rendering an otherwise well-performing model performs poorly. At model building and training time there is no easy way to identify if the error lies in the labels or the model itself. This often leads to spending a large amount of time trying to fix the problem. To avoid this, Label Evaluation features provides a set of functionalities to evaluate the labels and identify problematic ones based on measures of Inter Rater Agreement, and Correlations.
        
        
        # Usage
        
        Install the package:
        
        `pip install snlp`
        
        See the description of different functionalities with worked examples below. 
        
        ## **Text Analysis**
        
        *snlp* provides an easy to use function (`text_analysis.generate_report`) for analyzing text with an extensive analysis report. `text_analysis.generate_report` 
        receives as input a dataframe that contains a text column, and an optional number of label columns. Currently, `text_analysis.generate_report` can generate plots for up to 4
        numerical or categorical labels. See the example below for more details.
        
        ```python
        from snlp.text_analysis import generate_report
        
        generate_report(df=imdb_train,
                        out_dir='output_dir',
                        text_col='text',
                        label_cols=[('label', 'categorical')])
        
        ```
        
        The above script creates an analysis report that includes distribution plots and word clouds for different POS tags, for text, and bar plots and histograms for labels. You can specify up to 
        4 labels of type *categorical* or *numerical*. See the example below for including another label of *numerical* type. The report is automatically rendered in the browser via `plotly` default port assignment. But you also have the option of saving the report in an HTML format by setting the `save_report` argument to `True`. 
        
        ```python
        import numpy as np
        import random
        
        # In addition to the original label, for illustration purpose, let's create two random labels:
        imdb_train['numerical_label'] = np.random.randint(1, 500, imdb_train.shape[0])
        imdb_train['new_label'] = random.choices(['a', 'b', 'c', 'd'], [0.2, 0.5, 0.8, 0.9], k=imdb_train.shape[0])
        
        generate_report(df=imdb_train,
                        out_dir='output_dir',
                        text_col='text',
                        label_cols=[('label', 'categorical'), ('new_label', 'categorical'), ('numerical_label', 'numerical')])
        
        ```
        
        The above yields a report in HTML, with interactive `plotly` plots as can be seen in example screenshots below. 
        
        ![annotation1](/assets/annotation1.png)
        
         You can easily zoom in any part of the plot to a have a closer look:
        
        ![zoom](/assets/zoom.png)
        
        You can get word clouds for different part of speech tags, as can be seen in the below example where word clouds for nouns, adjectives and verbs are rendered:
        
        ![wc](/assets/wc.png)
        
        ## **Extraction of Multiword Expressions**
        
        Multiword Expressions (also known as collocations of fixed expressions) are phrases that function as a single semantic unit E.g. *swimming pool* and *climate change*. Multiword Expressions have application in a wide range of NLP tasks ranging from sentiment analysis to topic models and key-phrase extraction. 
        
        You can use `snlp` to identify different types of MWEs in your text leveraging statistical measures such as *PMI* and *NPMI*. To do so, first create an instance of `MWE` class:
        
        
        ```python
        from snlp.mwes import MWE
        my_mwe_types = ["NC", "JNC"]
        mwe = MWE(df=imdb_train, mwe_types=my_mwe_types, text_column='text')
        ```
        
        If the text in `text_column` is un-tokenized or poorly tokenized, `MWE` recognizes this issue at instantiation time and shows you a warning. If you already know that your text is not tokenized, you can run the same instantiation with flag `tokenize=True`. Next you need to run the method `build_count()`. Since creating counts is a time consuming procedure, it was implemented independently from `extract_mwes()` method that works on top of the output of `build_count()`. This way, you can get the counts which is a time consuming process once, and then run `extract_mwes()` several times with different parameters.
        
        ```python
        mwe.build_counts()
        mwe.extract_mwes()
        ```
        
        Running the above results in a json file, containing dictionary of mwe types defined in the `mwe_types` argument of `MWE`, to their association score (specified by `am` argument of `extract_mwes()`). Note that the MWEs in this json file are sorted with respect to their `am` score. All MWEs and their counts are stored in respective directories inside the `output_dir` argument of `MWE`. The default value is `tmp`. 
        
        ```
        NOUN-NOUN COMPOUNDS
        -------------------
        jet li
        clint eastwood
        monty python
        kung fu
        blade runner
        
        
        ADJECTIVE-NOUN COMPOUNDS
        ------------------------
        spinal tap
        martial arts
        citizen kane
        facial expressions
        global warming
        ```
        
        An important use of extracting MWEs is to treat them as a single token. Research shows that when fixed expressions are treated as a single token rather than the sum of their components, they can improve the performance of downstream applications such as classification and NER. Using the `replace_mwes` function, you can replace the extracted expressions in the corpus with their hyphenated version (global warming --> global-warming) so that they are considered a single token by downstream applications. A worked example can be seen below:
        
        ```python
        from snlp.mwes import replace_mwes
        new_df = replace_mwes(path_to_mwes='tmp/mwes/mwe_data.json', mwe_types=['NC', 'JNC'], df=imdb_train, text_column='text')
        new_df.to_csv('tmp/new_df.csv', sep='\t')
        ```
        
        
        ## **Identification of Statistically Redundant Words**
        
        Redundant words carry little value and can exacerbate the results of many NLP tasks. To solve this issue, traditionally, a pre-defined list of words, called stop words was defined and removed from the data. However, creating such a list is not optimal because in addition to being a rule-based and manual approach which does not generalize well, one has to assume that there is a universal list of stop words that represents highly low entropy words for all corpora, which is a very strong assumption and not necessarily a true assumption in many cases.
        
        To solve this issue, one can use a purely statistical solution which is completely automatic and does not make any universal assumption. It focuses only on the corpus at hand. Words can be represented with various statistics. For instance, they can be represented by their term frequency (tf) or inverse document frequency (idf). It can be then interpreted that terms with anomalous (very high or very low) statistics carry little value and can be discarded.
        SNLP enables you to identify such terms in an automatic fashion. The solution might seem complex behind the scene, as it firsts needs calculate certain statistics, gaussanize the distribution of the specified statistics (i.e. tf or ifd), and then identify the terms with anomalous values on the gaussanized distribution by looking at their z-score. However, the API is easy and convenient to use. The example below shows how you can use this API:
        
        ```python
        from snlp.preprocessing import RedunWords
        
        imdb_train = pd.read_csv('resources/data/imdb_train_sample.tsv', sep='\t', names=['label', 'text'])
        rw = RedunWords(imdb_train["text"], method='idf')
        ```
        
        Let the program automatically identify a set of redundant words:
        
        ```python
        red_words = rw.get_redundant_terms()
        ```
        
        
        Alternatively, you can manually set cut-off threshold for the specified score, by setting the manual Flag to True and specifying lower and upper cut-off thresholds. 
        ```python
        red_words = rw.get_redundant_terms(manual=True, manual_thresholds: dict={'lower_threshold':1, 'upper_threshold': 8})
        ```
        
        In order to get a better understanding of the distribution of the scores before setting the thresholds, you can run `show_plot()` method from `RedunWords` class to see this distribution:
        
        ```python
        rw.show_plot()
        ```
        
        When red_words is ready, you can filter the corpus:
        
        ```python
        # text must be a list of words
        res = " ".join([t for t in text if t not in redundant_terms])
        ```
        
        ## **Text Cleaning**
        
        *snlp* implements an easy to use and powerful function for cleaning up the text (`clean_text`). 
        Using, `clean_text`, you can choose what pattern to accept via `keep_pattern` argument, 
        what pattern to drop via `drop_patterns` argument, and what pattern to replace via `replace` argument. You can also specify the maximum length of tokens. 
        Let's use [Stanford's IMDB Sentiment Dataset](https://ai.stanford.edu/~amaas/data/sentiment/) as an example. A sample of this data can be found in `resources/data/imdb_train_sample.tsv`.
        
        
        ```python
        from snlp.preprocessing import clean_text
        
        imdb_train = pd.read_csv('data/imdb_train_sample.tsv', sep='\t', names=['label', 'text'])
        
        # Let's only keep alphanumeric tokens as well as important punctuation marks:
        keep_pattern='^[a-zA-Z0-9!.,?\';:$/_-]+$'
        
        # In this corpus, one can frequently see HTML tags such as `< br / >`. So let's drop them:
        drop_patterns={'< br / >'}
        
        # By skimming throw the text one can frequently see many patterns such as !!! or ???. Let's replace them:
        replace={'!!!':'!', '\?\?\?':'?'}
        
        # Finally, let's set the maximum length of a token to 15:
        maxlen=15
        
        imdb_train.text = imdb_train.text.apply(clean_text, args=(keep_pattern, drop_patterns, replace, maxlen,))
        ```
        
        Note that `clean_text` returns tokenized text. 
        
        
        ## References
        <a id="1">[1]</a> R. Csaky et al. - Improving Neural Conversational Models with Entropy-Based Data Filtering - In Proceedings of ACL 2019 - Florence, Italy.
        
        <a id="2">[2]</a> Maxime Peyrard - A Simple Theoretical Model of Importance for Summarization - In Proceedings of ACL 2019 - Florence, Italy.
        
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