import os import pandas as pd import numpy as np import streamlit as st import re import pickle def preprocess(q): q=str(q).lower().strip() q=q.replace('%',' percent ') q=q.replace('@',' at ') q=q.replace('$',' dollar ') q=q.replace('[math]','') q=q.replace(',000,000,000 ','b ') q=q.replace(',000,000 ','m ') q=q.replace(',000 ','k ') import re q=re.sub(r'([0-9]+)000000000',r'\1b',q) q=re.sub(r'([0-9]+)000000',r'\1m',q) q=re.sub(r'([0-9]+)000',r'\1k',q) contractions = { "ain't": "am not", "aren't": "are not", "can't": "can not", "can't've": "can not have", "'cause": "because", "could've": "could have", "couldn't": "could not", "couldn't've": "could not have", "didn't": "did not", "doesn't": "does not", "don't": "do not", "hadn't": "had not", "hadn't've": "had not have", "hasn't": "has not", "haven't": "have not", "he'd": "he would", "he'd've": "he would have", "he'll": "he will", "he'll've": "he will have", "he's": "he is", "how'd": "how did", "how'd'y": "how do you", "how'll": "how will", "how's": "how is", "i'd": "i would", "i'd've": "i would have", "i'll": "i will", "i'll've": "i will have", "i'm": "i am", "i've": "i have", "isn't": "is not", "it'd": "it would", "it'd've": "it would have", "it'll": "it will", "it'll've": "it will have", "it's": "it is", "let's": "let us", "ma'am": "madam", "mayn't": "may not", "might've": "might have", "mightn't": "might not", "mightn't've": "might not have", "must've": "must have", "mustn't": "must not", "mustn't've": "must not have", "needn't": "need not", "needn't've": "need not have", "o'clock": "of the clock", "oughtn't": "ought not", "oughtn't've": "ought not have", "shan't": "shall not", "sha'n't": "shall not", "shan't've": "shall not have", "she'd": "she would", "she'd've": "she would have", "she'll": "she will", "she'll've": "she will have", "she's": "she is", "should've": "should have", "shouldn't": "should not", "shouldn't've": "should not have", "so've": "so have", "so's": "so as", "that'd": "that would", "that'd've": "that would have", "that's": "that is", "there'd": "there would", "there'd've": "there would have", "there's": "there is", "they'd": "they would", "they'd've": "they would have", "they'll": "they will", "they'll've": "they will have", "they're": "they are", "they've": "they have", "to've": "to have", "wasn't": "was not", "we'd": "we would", "we'd've": "we would have", "we'll": "we will", "we'll've": "we will have", "we're": "we are", "we've": "we have", "weren't": "were not", "what'll": "what will", "what'll've": "what will have", "what're": "what are", "what's": "what is", "what've": "what have", "when's": "when is", "when've": "when have", "where'd": "where did", "where's": "where is", "where've": "where have", "who'll": "who will", "who'll've": "who will have", "who's": "who is", "who've": "who have", "why's": "why is", "why've": "why have", "will've": "will have", "won't": "will not", "won't've": "will not have", "would've": "would have", "wouldn't": "would not", "wouldn't've": "would not have", "y'all": "you all", "y'all'd": "you all would", "y'all'd've": "you all would have", "y'all're": "you all are", "y'all've": "you all have", "you'd": "you would", "you'd've": "you would have", "you'll": "you will", "you'll've": "you will have", "you're": "you are", "you've": "you have" } q_decontracted = [] for word in q.split(): if word in contractions: word = contractions[word] q_decontracted.append(word) q = ' '.join(q_decontracted) q = q.replace("'ve", " have") q = q.replace("n't", " not") q = q.replace("'re", " are") q = q.replace("'ll", " will") q=re.sub(re.compile('<.*?>'),'',q) import string q=q.translate(str.maketrans('', '', string.punctuation)) return q def common_words(row): w1=set(map(lambda word: word.lower().strip(),row['question1'].split(" "))) w2=set(map(lambda word: word.lower().strip(),row['question2'].split(" "))) return len(w1 & w2) def total_words(row): w1=set(map(lambda word: word.lower().strip(),row['question1'].split(" "))) w2=set(map(lambda word: word.lower().strip(),row['question2'].split(" "))) return len(w1) + len(w2) import nltk nltk.download("stopwords") from nltk.corpus import stopwords def fetch_token_features(row): q1 = row['question1'] q2 = row['question2'] SAFE_DIV = 0.0001 STOP_WORDS = stopwords.words("english") token_features = [0.0]*8 # Converting the Sentence into Tokens: q1_tokens = q1.split() q2_tokens = q2.split() if len(q1_tokens) == 0 or len(q2_tokens) == 0: return token_features # Get the non-stopwords in Questions q1_words = set([word for word in q1_tokens if word not in STOP_WORDS]) q2_words = set([word for word in q2_tokens if word not in STOP_WORDS]) #Get the stopwords in Questions q1_stops = set([word for word in q1_tokens if word in STOP_WORDS]) q2_stops = set([word for word in q2_tokens if word in STOP_WORDS]) # Get the common non-stopwords from Question pair common_word_count = len(q1_words.intersection(q2_words)) # Get the common stopwords from Question pair common_stop_count = len(q1_stops.intersection(q2_stops)) # Get the common Tokens from Question pair common_token_count = len(set(q1_tokens).intersection(set(q2_tokens))) token_features[0] = common_word_count / (min(len(q1_words), len(q2_words)) + SAFE_DIV) token_features[1] = common_word_count / (max(len(q1_words), len(q2_words)) + SAFE_DIV) token_features[2] = common_stop_count / (min(len(q1_stops), len(q2_stops)) + SAFE_DIV) token_features[3] = common_stop_count / (max(len(q1_stops), len(q2_stops)) + SAFE_DIV) token_features[4] = common_token_count / (min(len(q1_tokens), len(q2_tokens)) + SAFE_DIV) token_features[5] = common_token_count / (max(len(q1_tokens), len(q2_tokens)) + SAFE_DIV) # Last word of both question is same or not token_features[6] = int(q1_tokens[-1] == q2_tokens[-1]) # First word of both question is same or not token_features[7] = int(q1_tokens[0] == q2_tokens[0]) return token_features import distance def fetch_length_features(row): q1 = row['question1'] q2 = row['question2'] length_features = [0.0]*3 # Converting the Sentence into Tokens: q1_tokens = q1.split() q2_tokens = q2.split() if len(q1_tokens) == 0 or len(q2_tokens) == 0: return length_features # Absolute length features length_features[0] = abs(len(q1_tokens) - len(q2_tokens)) # Average Token Length of both Questions length_features[1] = (len(q1_tokens) + len(q2_tokens)) / 2 # Find the longest common substring strs = list(distance.lcsubstrings(q1, q2)) if strs: length_features[2] = len(strs[0]) / (min(len(q1), len(q2)) + 1) else: length_features[2] = 0.0 return length_features # Fuzzy Features from fuzzywuzzy import fuzz def fetch_fuzzy_features(row): q1 = row['question1'] q2 = row['question2'] fuzzy_features = [0.0]*4 # fuzz_ratio fuzzy_features[0] = fuzz.QRatio(q1, q2) # fuzz_partial_ratio fuzzy_features[1] = fuzz.partial_ratio(q1, q2) # token_sort_ratio fuzzy_features[2] = fuzz.token_sort_ratio(q1, q2) # token_set_ratio fuzzy_features[3] = fuzz.token_set_ratio(q1, q2) return fuzzy_features def all_prep(df): df['q1_len']=df['question1'].str.len() df['q2_len']=df['question2'].str.len() df['q1_num_words']=df['question1'].apply(lambda row: len(row.split(" "))) df['q2_num_words']=df['question2'].apply(lambda row: len(row.split(" "))) df['word_common']=df.apply(common_words,axis=1) df['word_total']=df.apply(total_words,axis=1) df['word_share']=round(df['word_common']/df['word_total'],2) token_features = df.apply(fetch_token_features, axis=1) df["cwc_min"] = list(map(lambda x: x[0], token_features)) df["cwc_max"] = list(map(lambda x: x[1], token_features)) df["csc_min"] = list(map(lambda x: x[2], token_features)) df["csc_max"] = list(map(lambda x: x[3], token_features)) df["ctc_min"] = list(map(lambda x: x[4], token_features)) df["ctc_max"] = list(map(lambda x: x[5], token_features)) df["last_word_eq"] = list(map(lambda x: x[6], token_features)) df["first_word_eq"] = list(map(lambda x: x[7], token_features)) length_features = df.apply(fetch_length_features, axis=1) df['abs_len_diff'] = list(map(lambda x: x[0], length_features)) df['mean_len'] = list(map(lambda x: x[1], length_features)) df['longest_substr_ratio'] = list(map(lambda x: x[2], length_features)) fuzzy_features = df.apply(fetch_fuzzy_features, axis=1) df['fuzz_ratio'] = list(map(lambda x: x[0], fuzzy_features)) df['fuzz_partial_ratio'] = list(map(lambda x: x[1], fuzzy_features)) df['token_sort_ratio'] = list(map(lambda x: x[2], fuzzy_features)) df['token_set_ratio'] = list(map(lambda x: x[3], fuzzy_features)) ndf2=df.drop(columns=['question1','question2']) import pickle import numpy as np with open("BOW.pkl", 'rb') as file: cv = pickle.load(file) questions=list(df['question1'])+list(df['question2']) q1_arr,q2_arr=np.vsplit(cv.transform(questions).toarray(),2) temp_df=pd.concat([pd.DataFrame(q1_arr,index=ndf2.index),pd.DataFrame(q2_arr,index=ndf2.index)],axis=1) temp_df=pd.concat([ndf2,temp_df],axis=1) temp_df.columns = temp_df.columns.astype(str) return temp_df def clear_text(): st.session_state["text1"] = "" st.session_state["text2"] = "" def main(): st.title('Duplicate Question Detection (Approach 1)') st.write("Feature Engineering, BOW , Random Forest") q1 = st.text_input("Enter Question1", key="text1") q2 = st.text_input("Enter Question2", key="text2") data=[] df = pd.DataFrame(data) df['question1']=[preprocess(q1)] df['question2']=[preprocess(q2)] with open("RF.pkl", 'rb') as file: rf = pickle.load(file) if st.button('Find'): z=rf.predict(all_prep(df))[0] if z==1: st.success("Duplicate") else: st.success("Not Duplicate") st.button("Clear", on_click=clear_text) if __name__=='__main__': main()