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import re |
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import datetime |
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from typing import TypeVar, Dict, List, Tuple |
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import time |
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from itertools import compress |
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import pandas as pd |
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import numpy as np |
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import torch |
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from threading import Thread |
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from transformers import pipeline, TextIteratorStreamer |
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from dataclasses import asdict, dataclass |
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from langchain.prompts import PromptTemplate |
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from langchain.vectorstores import FAISS |
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from langchain.retrievers import SVMRetriever |
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from langchain.text_splitter import RecursiveCharacterTextSplitter |
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from langchain.docstore.document import Document |
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import nltk |
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nltk.download('wordnet') |
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from nltk.corpus import stopwords |
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from nltk.tokenize import RegexpTokenizer |
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from nltk.stem import WordNetLemmatizer |
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import keybert |
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from span_marker import SpanMarkerModel |
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from gensim.corpora import Dictionary |
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from gensim.models import TfidfModel, OkapiBM25Model |
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from gensim.similarities import SparseMatrixSimilarity |
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import gradio as gr |
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torch.cuda.empty_cache() |
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PandasDataFrame = TypeVar('pd.core.frame.DataFrame') |
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embeddings = None |
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vectorstore = None |
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model_type = None |
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max_memory_length = 0 |
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full_text = "" |
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model = [] |
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tokenizer = [] |
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hlt_chunk_size = 15 |
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hlt_strat = [" ", ".", "!", "?", ":", "\n\n", "\n", ","] |
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hlt_overlap = 4 |
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ner_model = SpanMarkerModel.from_pretrained("tomaarsen/span-marker-mbert-base-multinerd") |
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kw_model = pipeline("feature-extraction", model="sentence-transformers/all-MiniLM-L6-v2") |
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if torch.cuda.is_available(): |
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torch_device = "cuda" |
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gpu_layers = 0 |
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else: |
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torch_device = "cpu" |
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gpu_layers = 0 |
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print("Running on device:", torch_device) |
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threads = 8 |
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print("CPU threads:", threads) |
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temperature: float = 0.1 |
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top_k: int = 3 |
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top_p: float = 1 |
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repetition_penalty: float = 1.3 |
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flan_alpaca_repetition_penalty: float = 1.3 |
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tinyllama_repetition_penalty: float = 1.5 |
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last_n_tokens: int = 64 |
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max_new_tokens: int = 512 |
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seed: int = 42 |
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reset: bool = False |
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stream: bool = True |
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threads: int = threads |
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batch_size:int = 256 |
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context_length:int = 2048 |
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sample = True |
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class CtransInitConfig_gpu: |
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def __init__(self, temperature=temperature, |
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top_k=top_k, |
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top_p=top_p, |
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repetition_penalty=repetition_penalty, |
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last_n_tokens=last_n_tokens, |
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max_new_tokens=max_new_tokens, |
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seed=seed, |
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reset=reset, |
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stream=stream, |
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threads=threads, |
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batch_size=batch_size, |
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context_length=context_length, |
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gpu_layers=gpu_layers): |
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self.temperature = temperature |
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self.top_k = top_k |
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self.top_p = top_p |
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self.repetition_penalty = repetition_penalty |
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self.last_n_tokens = last_n_tokens |
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self.max_new_tokens = max_new_tokens |
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self.seed = seed |
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self.reset = reset |
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self.stream = stream |
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self.threads = threads |
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self.batch_size = batch_size |
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self.context_length = context_length |
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self.gpu_layers = gpu_layers |
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def update_gpu(self, new_value): |
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self.gpu_layers = new_value |
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class CtransInitConfig_cpu(CtransInitConfig_gpu): |
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def __init__(self): |
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super().__init__() |
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self.gpu_layers = 0 |
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gpu_config = CtransInitConfig_gpu() |
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cpu_config = CtransInitConfig_cpu() |
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class CtransGenGenerationConfig: |
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def __init__(self, temperature=temperature, |
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top_k=top_k, |
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top_p=top_p, |
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repetition_penalty=repetition_penalty, |
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last_n_tokens=last_n_tokens, |
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seed=seed, |
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threads=threads, |
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batch_size=batch_size, |
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reset=True |
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): |
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self.temperature = temperature |
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self.top_k = top_k |
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self.top_p = top_p |
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self.repetition_penalty = repetition_penalty |
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self.last_n_tokens = last_n_tokens |
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self.seed = seed |
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self.threads = threads |
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self.batch_size = batch_size |
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self.reset = reset |
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def docs_to_faiss_save(docs_out:PandasDataFrame, embeddings=embeddings): |
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print(f"> Total split documents: {len(docs_out)}") |
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vectorstore_func = FAISS.from_documents(documents=docs_out, embedding=embeddings) |
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''' |
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#with open("vectorstore.pkl", "wb") as f: |
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#pickle.dump(vectorstore, f) |
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''' |
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global vectorstore |
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vectorstore = vectorstore_func |
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out_message = "Document processing complete" |
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return out_message |
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def base_prompt_templates(model_type = "Flan Alpaca"): |
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CONTENT_PROMPT = PromptTemplate( |
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template="{page_content}\n\n", |
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input_variables=["page_content"] |
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) |
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instruction_prompt_template_alpaca_quote = """### Instruction: |
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Quote directly from the SOURCE below that best answers the QUESTION. Only quote full sentences in the correct order. If you cannot find an answer, start your response with "My best guess is: ". |
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CONTENT: {summaries} |
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QUESTION: {question} |
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Response:""" |
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instruction_prompt_template_alpaca = """### Instruction: |
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### User: |
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Answer the QUESTION using information from the following CONTENT. |
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CONTENT: {summaries} |
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QUESTION: {question} |
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Response:""" |
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instruction_prompt_template_sheared_llama = """Answer the QUESTION using information from the following CONTENT. |
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CONTENT: {summaries} |
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QUESTION: {question} |
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Answer:""" |
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instruction_prompt_template_orca = """ |
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### System: |
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You are an AI assistant that follows instruction extremely well. Help as much as you can. |
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### User: |
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Answer the QUESTION with a short response using information from the following CONTENT. |
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CONTENT: {summaries} |
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QUESTION: {question} |
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### Response:""" |
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instruction_prompt_mistral_orca = """<|im_start|>system\n |
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You are an AI assistant that follows instruction extremely well. Help as much as you can. |
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<|im_start|>user\n |
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Answer the QUESTION using information from the following CONTENT. Respond with short answers that directly answer the question. |
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CONTENT: {summaries} |
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QUESTION: {question}\n |
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Answer:<|im_end|>""" |
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instruction_prompt_tinyllama_orca = """<|im_start|>system\n |
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You are an AI assistant that follows instruction extremely well. Help as much as you can. |
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<|im_start|>user\n |
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Answer the QUESTION using information from the following CONTENT. Only quote text that directly answers the question and nothing more. If you can't find an answer to the question, respond with "Sorry, I can't find an answer to that question.". |
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CONTENT: {summaries} |
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QUESTION: {question}\n |
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Answer:<|im_end|>""" |
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if model_type == "Flan Alpaca": |
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INSTRUCTION_PROMPT=PromptTemplate(template=instruction_prompt_template_alpaca, input_variables=['question', 'summaries']) |
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elif model_type == "Orca Mini": |
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INSTRUCTION_PROMPT=PromptTemplate(template=instruction_prompt_template_orca, input_variables=['question', 'summaries']) |
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return INSTRUCTION_PROMPT, CONTENT_PROMPT |
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def generate_expanded_prompt(inputs: Dict[str, str], instruction_prompt, content_prompt, extracted_memory, vectorstore, embeddings): |
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question = inputs["question"] |
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chat_history = inputs["chat_history"] |
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new_question_kworded = adapt_q_from_chat_history(question, chat_history, extracted_memory) |
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docs_keep_as_doc, doc_df, docs_keep_out = hybrid_retrieval(new_question_kworded, vectorstore, embeddings, k_val = 5, out_passages = 1, |
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vec_score_cut_off = 1, vec_weight = 1, bm25_weight = 1, svm_weight = 1) |
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docs_keep_as_doc, doc_df = get_expanded_passages(vectorstore, docs_keep_out, width=3) |
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if docs_keep_as_doc == []: |
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{"answer": "I'm sorry, I couldn't find a relevant answer to this question.", "sources":"I'm sorry, I couldn't find a relevant source for this question."} |
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doc_df['meta_clean'] = [f"<b>{' '.join(f'{k}: {v}' for k, v in d.items() if k != 'page_section')}</b>" for d in doc_df['metadata']] |
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doc_df['content_meta'] = doc_df['meta_clean'].astype(str) + ".<br><br>" + doc_df['page_content'].astype(str) |
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modified_page_content = [f" SOURCE {i+1} - {word}" for i, word in enumerate(doc_df['page_content'])] |
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docs_content_string = ''.join(modified_page_content) |
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sources_docs_content_string = '<br><br>'.join(doc_df['content_meta']) |
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instruction_prompt_out = instruction_prompt.format(question=new_question_kworded, summaries=docs_content_string) |
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print('Final prompt is: ') |
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print(instruction_prompt_out) |
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return instruction_prompt_out, sources_docs_content_string, new_question_kworded |
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def create_full_prompt(user_input, history, extracted_memory, vectorstore, embeddings, model_type): |
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print("\n==== date/time: " + str(datetime.datetime.now()) + " ====") |
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print("User input: " + user_input) |
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history = history or [] |
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instruction_prompt, content_prompt = base_prompt_templates(model_type=model_type) |
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instruction_prompt_out, docs_content_string, new_question_kworded =\ |
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generate_expanded_prompt({"question": user_input, "chat_history": history}, |
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instruction_prompt, content_prompt, extracted_memory, vectorstore, embeddings) |
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history.append(user_input) |
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print("Output history is:") |
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print(history) |
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return history, docs_content_string, instruction_prompt_out |
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def produce_streaming_answer_chatbot(history, full_prompt, model_type): |
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if model_type == "Flan Alpaca": |
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model_inputs = tokenizer(text=full_prompt, return_tensors="pt", return_attention_mask=False).to(torch_device) |
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streamer = TextIteratorStreamer(tokenizer, timeout=120., skip_prompt=True, skip_special_tokens=True) |
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generate_kwargs = dict( |
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model_inputs, |
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streamer=streamer, |
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max_new_tokens=max_new_tokens, |
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do_sample=sample, |
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repetition_penalty=repetition_penalty, |
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top_p=top_p, |
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temperature=temperature, |
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top_k=top_k |
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) |
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t = Thread(target=model.generate, kwargs=generate_kwargs) |
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t.start() |
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start = time.time() |
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NUM_TOKENS=0 |
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print('-'*4+'Start Generation'+'-'*4) |
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history[-1][1] = "" |
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for new_text in streamer: |
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if new_text == None: new_text = "" |
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history[-1][1] += new_text |
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NUM_TOKENS+=1 |
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yield history |
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time_generate = time.time() - start |
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print('\n') |
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print('-'*4+'End Generation'+'-'*4) |
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print(f'Num of generated tokens: {NUM_TOKENS}') |
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print(f'Time for complete generation: {time_generate}s') |
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print(f'Tokens per secound: {NUM_TOKENS/time_generate}') |
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print(f'Time per token: {(time_generate/NUM_TOKENS)*1000}ms') |
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elif model_type == "Orca Mini": |
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tokens = model.tokenize(full_prompt) |
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gen_config = CtransGenGenerationConfig() |
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start = time.time() |
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NUM_TOKENS=0 |
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print('-'*4+'Start Generation'+'-'*4) |
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history[-1][1] = "" |
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for new_text in model.generate(tokens, **vars(gen_config)): |
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if new_text == None: new_text = "" |
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history[-1][1] += model.detokenize(new_text) |
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NUM_TOKENS+=1 |
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yield history |
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time_generate = time.time() - start |
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print('\n') |
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print('-'*4+'End Generation'+'-'*4) |
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print(f'Num of generated tokens: {NUM_TOKENS}') |
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print(f'Time for complete generation: {time_generate}s') |
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print(f'Tokens per secound: {NUM_TOKENS/time_generate}') |
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print(f'Time per token: {(time_generate/NUM_TOKENS)*1000}ms') |
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def adapt_q_from_chat_history(question, chat_history, extracted_memory, keyword_model=""): |
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chat_history_str, chat_history_first_q, chat_history_first_ans, max_memory_length = _get_chat_history(chat_history) |
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if chat_history_str: |
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extracted_memory = extracted_memory |
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new_question_kworded = str(extracted_memory) + ". " + question |
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else: |
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new_question_kworded = question |
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return new_question_kworded |
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def create_doc_df(docs_keep_out): |
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content=[] |
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meta=[] |
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meta_url=[] |
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page_section=[] |
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score=[] |
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for item in docs_keep_out: |
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content.append(item[0].page_content) |
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meta.append(item[0].metadata) |
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meta_url.append(item[0].metadata['source']) |
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page_section.append(item[0].metadata['page_section']) |
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score.append(item[1]) |
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doc_df = pd.DataFrame(list(zip(content, meta, page_section, meta_url, score)), |
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columns =['page_content', 'metadata', 'page_section', 'meta_url', 'score']) |
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docs_content = doc_df['page_content'].astype(str) |
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doc_df['full_url'] = "https://" + doc_df['meta_url'] |
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return doc_df |
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def hybrid_retrieval(new_question_kworded, vectorstore, embeddings, k_val, out_passages, |
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vec_score_cut_off, vec_weight, bm25_weight, svm_weight): |
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docs = vectorstore.similarity_search_with_score(new_question_kworded, k=k_val) |
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print("Docs from similarity search:") |
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print(docs) |
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docs_len = [len(x[0].page_content) for x in docs] |
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docs_scores = [x[1] for x in docs] |
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score_more_limit = pd.Series(docs_scores) < vec_score_cut_off |
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docs_keep = list(compress(docs, score_more_limit)) |
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if docs_keep == []: |
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docs_keep_as_doc = [] |
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docs_content = [] |
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docs_url = [] |
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return docs_keep_as_doc, docs_content, docs_url |
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length_more_limit = pd.Series(docs_len) >= 100 |
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docs_keep = list(compress(docs_keep, length_more_limit)) |
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if docs_keep == []: |
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docs_keep_as_doc = [] |
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docs_content = [] |
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docs_url = [] |
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return docs_keep_as_doc, docs_content, docs_url |
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docs_keep_as_doc = [x[0] for x in docs_keep] |
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docs_keep_length = len(docs_keep_as_doc) |
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if docs_keep_length == 1: |
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content=[] |
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meta_url=[] |
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score=[] |
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for item in docs_keep: |
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content.append(item[0].page_content) |
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meta_url.append(item[0].metadata['source']) |
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score.append(item[1]) |
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doc_df = pd.DataFrame(list(zip(content, meta_url, score)), |
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columns =['page_content', 'meta_url', 'score']) |
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docs_content = doc_df['page_content'].astype(str) |
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docs_url = doc_df['meta_url'] |
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return docs_keep_as_doc, docs_content, docs_url |
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if out_passages > docs_keep_length: |
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out_passages = docs_keep_length |
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k_val = docs_keep_length |
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vec_rank = [*range(1, docs_keep_length+1)] |
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vec_score = [(docs_keep_length/x)*vec_weight for x in vec_rank] |
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content_keep=[] |
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for item in docs_keep: |
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content_keep.append(item[0].page_content) |
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corpus = corpus = [doc.lower().split() for doc in content_keep] |
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dictionary = Dictionary(corpus) |
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bm25_model = OkapiBM25Model(dictionary=dictionary) |
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bm25_corpus = bm25_model[list(map(dictionary.doc2bow, corpus))] |
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bm25_index = SparseMatrixSimilarity(bm25_corpus, num_docs=len(corpus), num_terms=len(dictionary), |
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normalize_queries=False, normalize_documents=False) |
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query = new_question_kworded.lower().split() |
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tfidf_model = TfidfModel(dictionary=dictionary, smartirs='bnn') |
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tfidf_query = tfidf_model[dictionary.doc2bow(query)] |
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similarities = np.array(bm25_index[tfidf_query]) |
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temp = similarities.argsort() |
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ranks = np.arange(len(similarities))[temp.argsort()][::-1] |
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pairs = list(zip(ranks, docs_keep_as_doc)) |
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pairs.sort() |
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bm25_result = [value for ranks, value in pairs] |
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bm25_rank=[] |
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bm25_score = [] |
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for vec_item in docs_keep: |
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x = 0 |
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for bm25_item in bm25_result: |
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x = x + 1 |
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if bm25_item.page_content == vec_item[0].page_content: |
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bm25_rank.append(x) |
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bm25_score.append((docs_keep_length/x)*bm25_weight) |
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svm_retriever = SVMRetriever.from_texts(content_keep, embeddings, k = k_val) |
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svm_result = svm_retriever.get_relevant_documents(new_question_kworded) |
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svm_rank=[] |
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svm_score = [] |
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for vec_item in docs_keep: |
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x = 0 |
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for svm_item in svm_result: |
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x = x + 1 |
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if svm_item.page_content == vec_item[0].page_content: |
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svm_rank.append(x) |
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svm_score.append((docs_keep_length/x)*svm_weight) |
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final_score = [a + b + c for a, b, c in zip(vec_score, bm25_score, svm_score)] |
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final_rank = [sorted(final_score, reverse=True).index(x)+1 for x in final_score] |
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final_rank = list(pd.Series(final_rank).rank(method='first')) |
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best_rank_index_pos = [] |
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for x in range(1,out_passages+1): |
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try: |
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best_rank_index_pos.append(final_rank.index(x)) |
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except IndexError: |
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pass |
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best_rank_pos_series = pd.Series(best_rank_index_pos) |
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docs_keep_out = [docs_keep[i] for i in best_rank_index_pos] |
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docs_keep_as_doc = [x[0] for x in docs_keep_out] |
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doc_df = create_doc_df(docs_keep_out) |
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|
|
return docs_keep_as_doc, doc_df, docs_keep_out |
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|
|
def get_expanded_passages(vectorstore, docs, width): |
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|
|
""" |
|
Extracts expanded passages based on given documents and a width for context. |
|
|
|
Parameters: |
|
- vectorstore: The primary data source. |
|
- docs: List of documents to be expanded. |
|
- width: Number of documents to expand around a given document for context. |
|
|
|
Returns: |
|
- expanded_docs: List of expanded Document objects. |
|
- doc_df: DataFrame representation of expanded_docs. |
|
""" |
|
|
|
from collections import defaultdict |
|
|
|
def get_docs_from_vstore(vectorstore): |
|
vector = vectorstore.docstore._dict |
|
return list(vector.items()) |
|
|
|
def extract_details(docs_list): |
|
docs_list_out = [tup[1] for tup in docs_list] |
|
content = [doc.page_content for doc in docs_list_out] |
|
meta = [doc.metadata for doc in docs_list_out] |
|
return ''.join(content), meta[0], meta[-1] |
|
|
|
def get_parent_content_and_meta(vstore_docs, width, target): |
|
target_range = range(max(0, target - width), min(len(vstore_docs), target + width + 1)) |
|
parent_vstore_out = [vstore_docs[i] for i in target_range] |
|
|
|
content_str_out, meta_first_out, meta_last_out = [], [], [] |
|
for _ in parent_vstore_out: |
|
content_str, meta_first, meta_last = extract_details(parent_vstore_out) |
|
content_str_out.append(content_str) |
|
meta_first_out.append(meta_first) |
|
meta_last_out.append(meta_last) |
|
return content_str_out, meta_first_out, meta_last_out |
|
|
|
def merge_dicts_except_source(d1, d2): |
|
merged = {} |
|
for key in d1: |
|
if key != "source": |
|
merged[key] = str(d1[key]) + " to " + str(d2[key]) |
|
else: |
|
merged[key] = d1[key] |
|
return merged |
|
|
|
def merge_two_lists_of_dicts(list1, list2): |
|
return [merge_dicts_except_source(d1, d2) for d1, d2 in zip(list1, list2)] |
|
|
|
|
|
vstore_docs = get_docs_from_vstore(vectorstore) |
|
doc_sources = {doc.metadata['source'] for doc, _ in docs} |
|
vstore_docs = [(k, v) for k, v in vstore_docs if v.metadata.get('source') in doc_sources] |
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|
|
|
|
vstore_by_source = defaultdict(list) |
|
for k, v in vstore_docs: |
|
vstore_by_source[v.metadata['source']].append((k, v)) |
|
|
|
expanded_docs = [] |
|
for doc, score in docs: |
|
search_source = doc.metadata['source'] |
|
search_section = doc.metadata['page_section'] |
|
parent_vstore_meta_section = [doc.metadata['page_section'] for _, doc in vstore_by_source[search_source]] |
|
search_index = parent_vstore_meta_section.index(search_section) if search_section in parent_vstore_meta_section else -1 |
|
|
|
content_str, meta_first, meta_last = get_parent_content_and_meta(vstore_by_source[search_source], width, search_index) |
|
meta_full = merge_two_lists_of_dicts(meta_first, meta_last) |
|
|
|
expanded_doc = (Document(page_content=content_str[0], metadata=meta_full[0]), score) |
|
expanded_docs.append(expanded_doc) |
|
|
|
doc_df = create_doc_df(expanded_docs) |
|
|
|
return expanded_docs, doc_df |
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|
|
def highlight_found_text(search_text: str, full_text: str, hlt_chunk_size:int=hlt_chunk_size, hlt_strat:List=hlt_strat, hlt_overlap:int=hlt_overlap) -> str: |
|
""" |
|
Highlights occurrences of search_text within full_text. |
|
|
|
Parameters: |
|
- search_text (str): The text to be searched for within full_text. |
|
- full_text (str): The text within which search_text occurrences will be highlighted. |
|
|
|
Returns: |
|
- str: A string with occurrences of search_text highlighted. |
|
|
|
Example: |
|
>>> highlight_found_text("world", "Hello, world! This is a test. Another world awaits.") |
|
'Hello, <mark style="color:black;">world</mark>! This is a test. Another <mark style="color:black;">world</mark> awaits.' |
|
""" |
|
|
|
def extract_text_from_input(text, i=0): |
|
if isinstance(text, str): |
|
return text.replace(" ", " ").strip() |
|
elif isinstance(text, list): |
|
return text[i][0].replace(" ", " ").strip() |
|
else: |
|
return "" |
|
|
|
def extract_search_text_from_input(text): |
|
if isinstance(text, str): |
|
return text.replace(" ", " ").strip() |
|
elif isinstance(text, list): |
|
return text[-1][1].replace(" ", " ").strip() |
|
else: |
|
return "" |
|
|
|
full_text = extract_text_from_input(full_text) |
|
search_text = extract_search_text_from_input(search_text) |
|
|
|
|
|
|
|
text_splitter = RecursiveCharacterTextSplitter( |
|
chunk_size=hlt_chunk_size, |
|
separators=hlt_strat, |
|
chunk_overlap=hlt_overlap, |
|
) |
|
sections = text_splitter.split_text(search_text) |
|
|
|
found_positions = {} |
|
for x in sections: |
|
text_start_pos = 0 |
|
while text_start_pos != -1: |
|
text_start_pos = full_text.find(x, text_start_pos) |
|
if text_start_pos != -1: |
|
found_positions[text_start_pos] = text_start_pos + len(x) |
|
text_start_pos += 1 |
|
|
|
|
|
sorted_starts = sorted(found_positions.keys()) |
|
combined_positions = [] |
|
if sorted_starts: |
|
current_start, current_end = sorted_starts[0], found_positions[sorted_starts[0]] |
|
for start in sorted_starts[1:]: |
|
if start <= (current_end + 10): |
|
current_end = max(current_end, found_positions[start]) |
|
else: |
|
combined_positions.append((current_start, current_end)) |
|
current_start, current_end = start, found_positions[start] |
|
combined_positions.append((current_start, current_end)) |
|
|
|
|
|
pos_tokens = [] |
|
prev_end = 0 |
|
for start, end in combined_positions: |
|
if end-start > 15: |
|
pos_tokens.append(full_text[prev_end:start]) |
|
pos_tokens.append('<mark style="color:black;">' + full_text[start:end] + '</mark>') |
|
prev_end = end |
|
pos_tokens.append(full_text[prev_end:]) |
|
|
|
return "".join(pos_tokens) |
|
|
|
|
|
|
|
|
|
def clear_chat(chat_history_state, sources, chat_message, current_topic): |
|
chat_history_state = [] |
|
sources = '' |
|
chat_message = '' |
|
current_topic = '' |
|
|
|
return chat_history_state, sources, chat_message, current_topic |
|
|
|
def _get_chat_history(chat_history: List[Tuple[str, str]], max_memory_length:int = max_memory_length): |
|
|
|
if (not chat_history) | (max_memory_length == 0): |
|
chat_history = [] |
|
|
|
if len(chat_history) > max_memory_length: |
|
chat_history = chat_history[-max_memory_length:] |
|
|
|
|
|
|
|
first_q = "" |
|
first_ans = "" |
|
for human_s, ai_s in chat_history: |
|
first_q = human_s |
|
first_ans = ai_s |
|
|
|
|
|
break |
|
|
|
conversation = "" |
|
for human_s, ai_s in chat_history: |
|
human = f"Human: " + human_s |
|
ai = f"Assistant: " + ai_s |
|
conversation += "\n" + "\n".join([human, ai]) |
|
|
|
return conversation, first_q, first_ans, max_memory_length |
|
|
|
def add_inputs_answer_to_history(user_message, history, current_topic): |
|
|
|
if history is None: |
|
history = [("","")] |
|
|
|
|
|
|
|
chat_history_str, chat_history_first_q, chat_history_first_ans, max_memory_length = _get_chat_history(history) |
|
|
|
|
|
|
|
if (len(history) == 1) | (len(history) > max_memory_length): |
|
|
|
|
|
|
|
|
|
first_q_and_first_ans = str(chat_history_first_q) + " " + str(chat_history_first_ans) |
|
|
|
keywords = keybert_keywords(first_q_and_first_ans, n = 8, kw_model=kw_model) |
|
|
|
|
|
|
|
ordered_tokens = set() |
|
result = [] |
|
for word in keywords: |
|
if word not in ordered_tokens: |
|
ordered_tokens.add(word) |
|
result.append(word) |
|
|
|
extracted_memory = ' '.join(result) |
|
|
|
else: extracted_memory=current_topic |
|
|
|
print("Extracted memory is:") |
|
print(extracted_memory) |
|
|
|
|
|
return history, extracted_memory |
|
|
|
|
|
|
|
def remove_q_stopwords(question): |
|
|
|
text = question.lower() |
|
|
|
|
|
text = re.sub('[0-9]', '', text) |
|
|
|
tokenizer = RegexpTokenizer(r'\w+') |
|
text_tokens = tokenizer.tokenize(text) |
|
|
|
tokens_without_sw = [word for word in text_tokens if not word in stopwords] |
|
|
|
|
|
ordered_tokens = set() |
|
result = [] |
|
for word in tokens_without_sw: |
|
if word not in ordered_tokens: |
|
ordered_tokens.add(word) |
|
result.append(word) |
|
|
|
|
|
|
|
new_question_keywords = ' '.join(result) |
|
return new_question_keywords |
|
|
|
def remove_q_ner_extractor(question): |
|
|
|
predict_out = ner_model.predict(question) |
|
|
|
|
|
|
|
predict_tokens = [' '.join(v for k, v in d.items() if k == 'span') for d in predict_out] |
|
|
|
|
|
ordered_tokens = set() |
|
result = [] |
|
for word in predict_tokens: |
|
if word not in ordered_tokens: |
|
ordered_tokens.add(word) |
|
result.append(word) |
|
|
|
|
|
|
|
new_question_keywords = ' '.join(result).lower() |
|
return new_question_keywords |
|
|
|
def apply_lemmatize(text, wnl=WordNetLemmatizer()): |
|
|
|
def prep_for_lemma(text): |
|
|
|
|
|
text = re.sub('[0-9]', '', text) |
|
print(text) |
|
|
|
tokenizer = RegexpTokenizer(r'\w+') |
|
text_tokens = tokenizer.tokenize(text) |
|
|
|
|
|
return text_tokens |
|
|
|
tokens = prep_for_lemma(text) |
|
|
|
def lem_word(word): |
|
|
|
if len(word) > 3: out_word = wnl.lemmatize(word) |
|
else: out_word = word |
|
|
|
return out_word |
|
|
|
return [lem_word(token) for token in tokens] |
|
|
|
def keybert_keywords(text, n, kw_model): |
|
tokens_lemma = apply_lemmatize(text) |
|
lemmatised_text = ' '.join(tokens_lemma) |
|
|
|
keywords_text = keybert.KeyBERT(model=kw_model).extract_keywords(lemmatised_text, stop_words='english', top_n=n, |
|
keyphrase_ngram_range=(1, 1)) |
|
keywords_list = [item[0] for item in keywords_text] |
|
|
|
return keywords_list |
|
|
|
|
|
def turn_off_interactivity(user_message, history): |
|
return gr.update(value="", interactive=False), history + [[user_message, None]] |
|
|
|
def restore_interactivity(): |
|
return gr.update(interactive=True) |
|
|
|
def update_message(dropdown_value): |
|
return gr.Textbox.update(value=dropdown_value) |
|
|
|
def hide_block(): |
|
return gr.Radio.update(visible=False) |
|
|
|
|
|
|
|
def vote(data: gr.LikeData, chat_history, instruction_prompt_out, model_type): |
|
import os |
|
import pandas as pd |
|
|
|
chat_history_last = str(str(chat_history[-1][0]) + " - " + str(chat_history[-1][1])) |
|
|
|
response_df = pd.DataFrame(data={"thumbs_up":data.liked, |
|
"chosen_response":data.value, |
|
"input_prompt":instruction_prompt_out, |
|
"chat_history":chat_history_last, |
|
"model_type": model_type, |
|
"date_time": pd.Timestamp.now()}, index=[0]) |
|
|
|
if data.liked: |
|
print("You upvoted this response: " + data.value) |
|
|
|
if os.path.isfile("thumbs_up_data.csv"): |
|
existing_thumbs_up_df = pd.read_csv("thumbs_up_data.csv") |
|
thumbs_up_df_concat = pd.concat([existing_thumbs_up_df, response_df], ignore_index=True).drop("Unnamed: 0",axis=1, errors="ignore") |
|
thumbs_up_df_concat.to_csv("thumbs_up_data.csv") |
|
else: |
|
response_df.to_csv("thumbs_up_data.csv") |
|
|
|
else: |
|
print("You downvoted this response: " + data.value) |
|
|
|
if os.path.isfile("thumbs_down_data.csv"): |
|
existing_thumbs_down_df = pd.read_csv("thumbs_down_data.csv") |
|
thumbs_down_df_concat = pd.concat([existing_thumbs_down_df, response_df], ignore_index=True).drop("Unnamed: 0",axis=1, errors="ignore") |
|
thumbs_down_df_concat.to_csv("thumbs_down_data.csv") |
|
else: |
|
response_df.to_csv("thumbs_down_data.csv") |
|
|