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#loading tfidf dataset
import pandas as pd
newsdf_sample = pd.read_excel("complete_tfidf_25.xlsx",engine="openpyxl")
print("file size",len(newsdf_sample))
#preprocessing for better tokenization (needed for tfidf)
import nltk
nltk.download('stopwords')
nltk.download('wordnet')
nltk.download('omw-1.4')
from nltk.corpus import stopwords
stopwords_list = stopwords.words('english')
stopwords_list
def process_row(row):
import re
from textblob import Word
from string import punctuation
from nltk.stem.snowball import SnowballStemmer
#Mail address
row = re.sub('(\S+@\S+)(com|\s+com)', ' ', row)
#Username
row = re.sub('(\S+@\S+)', ' ', row)
# print('username',len(row.split()))
#punctuation
punctuation = punctuation + '\n' + 'ββ,ββ-β' + '0123456789' +"\t"
row = ''.join(word for word in row if word not in punctuation)
# print('punctuation',len(row.split()))
# print('punctuation',row)
#Lower case
row = row.lower()
# print('lower',len(row.split()))
#Stopwords
stop = stopwords_list
row = ' '.join(word for word in row.split() if word not in stop )
# print('stop',len(row.split()))
# print('stop',row)
# Lemma
row = " ".join([Word(word).lemmatize() for word in row.split()])
# print('lemma',len(row.split()))
# print('lemma',row)
#Stemming
stemmer = SnowballStemmer(language='english')
row = " ".join([stemmer.stem(word) for word in row.split()])
# print('stem',len(row.split()))
# print('stem',row)
#Extra whitespace
row = re.sub('\s{1,}', ' ', row)
# print('extra white',len(row.split()))
row = " ".join([word for word in row.split() if len(word) > 2])
return row
import pickle
kmeans_tfidf = pickle.load( open( "kmeans_tfidf_25_complete.p", "rb" ) )
vectorizer = pickle.load(open("tfidf_vectorizer_complete.p","rb"))
import matplotlib.pyplot as plt
from wordcloud import WordCloud
dictt_cluster_words={}
for i in range(0,25):
# print(i)
temp_df = newsdf_sample[newsdf_sample.exp25==i]
text_list= temp_df["tfidf_cleaned"].values
text_list = [element for element in text_list if str(element) != "nan"]
single_text = " ".join(text_list)
wordcloud = WordCloud(width = 1000, height = 500, max_words=1000).generate(single_text)
dictt_cluster_words[i] = wordcloud.words_
#summarization model
from transformers import PegasusForConditionalGeneration, PegasusTokenizer
from transformers import pipeline
import torch
model_name = 'google/pegasus-cnn_dailymail'
device = "cuda" if torch.cuda.is_available() else "cpu"
tokenizer = PegasusTokenizer.from_pretrained(model_name)
model = PegasusForConditionalGeneration.from_pretrained(model_name).to(device)
def return_summary(text):
src_text =[text]
batch = tokenizer(src_text, truncation=True, padding="longest", return_tensors="pt").to(device)
translated = model.generate(**batch)
tgt_text = tokenizer.batch_decode(translated, skip_special_tokens=True)
tgt_text= tgt_text[0].replace("<n>"," ")
return tgt_text
############
def return_squad_answer(question, relevant_text):
qa_pipeline = pipeline(
"question-answering",
model="mvonwyl/distilbert-base-uncased-finetuned-squad2",#csarron/bert-base-uncased-squad-v1",
tokenizer="mvonwyl/distilbert-base-uncased-finetuned-squad2",#csarron/bert-base-uncased-squad-v1"
)
predictions = qa_pipeline({
'context': relevant_text,
'question': question
})
print(predictions)
return predictions["answer"]
#keyword based cluster selection would be better
#document selection based on tfidf vector
import numpy as np
import math
def l2_norm(a):
return math.sqrt(np.dot(a,a))
def cosine_similarity(a,b):
return abs(np.dot(a,b)/ (l2_norm(a) * l2_norm(b)))
def return_selected_cluster(ques):
ques_clean = process_row(ques)
count_tokens = len(ques_clean.split())
cluster_selected =-1
cluster_score =0
for clus_id in dictt_cluster_words:
score_temp=0
matched_token=0
for word in ques_clean.split():
dictt_temp = dictt_cluster_words[clus_id]
if word in dictt_temp:
matched_token+=1
score_temp+=dictt_temp[word]
score_temp*= (matched_token/count_tokens)
if score_temp>cluster_score:
cluster_selected = clus_id
cluster_score = score_temp
return cluster_selected
def get_summary_answer(Question):
print("question: ", Question)
cluster_selected = return_selected_cluster(Question)
print("cluster selected - ",cluster_selected)
temp_df = newsdf_sample[newsdf_sample.exp25==cluster_selected]
tfidf_ques = vectorizer.transform([process_row(Question)]).todense()
cosine_score = []
for sent in temp_df["tfidf_cleaned"].values:
val = vectorizer.transform([sent]).todense()
# print(np.array(tfidf_ques)[0], np.array(val)[0])
cos_score = cosine_similarity(np.array(tfidf_ques)[0],np.array(val)[0])
cosine_score.append(cos_score)
temp_df["cos_score"] = cosine_score
temp_df = temp_df.sort_values(by=['cos_score'], ascending=False)
relevant_docs = temp_df["cleaned_doc"][:20]
relevant_text = " ".join(relevant_docs)
print("relevant_text", relevant_text)
# print("summary - ",return_summary(relevant_text))
# print("squad answer- ",return_squad_answer(ques, relevant_text))
summary = return_summary(relevant_text)
squad_answer = return_squad_answer(Question, relevant_text)
relevant_text = " ".join(relevant_text.split()[:min(250,len(relevant_text.split()))])
return relevant_text, summary, squad_answer
import gradio as gr
iface = gr.Interface(fn = get_summary_answer,
inputs = gr.Textbox(type="text", label="Type your question"),
# outputs = ["text", "text"],
outputs = [
gr.Textbox(type="text", value=1, label="Relevant text"),
gr.Textbox(type="text", value=2, label="Answer from Generative Model"),
gr.Textbox(type="text", value=3, label="Answer from SQuAD model"),
],
title = "20NewsGroup_QA",
description ="Returns answer from 20NewsGroup dataset")
iface.launch(inline = False, debug = True) |