import os import string from typing import Any, Dict, List, Tuple, Union import chromadb import numpy as np import openai import pandas as pd import requests import streamlit as st from datasets import load_dataset from langchain.document_loaders import TextLoader from langchain.embeddings.sentence_transformer import SentenceTransformerEmbeddings from langchain.text_splitter import CharacterTextSplitter from langchain.vectorstores import Chroma from scipy.spatial.distance import cosine openai.api_key = os.environ["OPENAI_API_KEY"] def merge_dataframes(dataframes: List[pd.DataFrame]) -> pd.DataFrame: """ Merges a list of pandas DataFrames into a single DataFrame. This function concatenates the given DataFrames and filters the resulting DataFrame to only include the columns 'context', 'questions', and 'answers'. Parameters: dataframes (List[pd.DataFrame]): A list of DataFrames to be merged. Returns: pd.DataFrame: The concatenated DataFrame containing only the specified columns. """ # Concatenate the list of dataframes combined_dataframe = pd.concat( dataframes, ignore_index=True ) # Combine all dataframes into one # Ensure that the resulting dataframe only contains the columns "context", "questions", "answers" combined_dataframe = combined_dataframe[ ["context", "questions", "answers"] ] # Filter for specific columns return combined_dataframe # Return the merged and filtered DataFrame def call_chatgpt(prompt: str) -> str: """ Uses the OpenAI API to generate an AI response to a prompt. Args: prompt: A string representing the prompt to send to the OpenAI API. Returns: A string representing the AI's generated response. """ # Use the OpenAI API to generate a response based on the input prompt. response = openai.Completion.create( model="gpt-3.5-turbo-instruct", prompt=prompt, temperature=0.5, max_tokens=500, top_p=1, frequency_penalty=0, presence_penalty=0, ) # Extract the text from the first (and only) choice in the response output. ans = response.choices[0]["text"] # Return the generated AI response. return ans def openai_text_embedding(prompt: str) -> str: """ Retrieves the text embedding for a given prompt using OpenAI's text-embedding model. This function utilizes OpenAI's API to generate an embedding for the input text. It specifically uses the "text-embedding-ada-002" model. Parameters: prompt (str): The text input for which to generate an embedding. Returns: str: A string representation of the text embedding. """ # Call OpenAI API to create a text embedding return openai.Embedding.create(input=prompt, model="text-embedding-ada-002")[ "data" ][0][ "embedding" ] # Retrieve the embedding from the response def calculate_sts_openai_score(sentence1: str, sentence2: str) -> float: """ Calculates the Semantic Textual Similarity (STS) between two sentences using OpenAI's text-embedding model. This function computes embeddings for each sentence and then calculates the cosine similarity between these embeddings. A higher score indicates greater similarity. Parameters: sentence1 (str): The first sentence for similarity comparison. sentence2 (str): The second sentence for similarity comparison. Returns: float: The STS score representing the similarity between sentence1 and sentence2. """ # Compute sentence embeddings embedding1 = openai_text_embedding(sentence1) # Flatten the embedding array embedding2 = openai_text_embedding(sentence2) # Flatten the embedding array # Convert embeddings to NumPy arrays embedding1 = np.asarray(embedding1) embedding2 = np.asarray(embedding2) # Calculate cosine similarity between the embeddings # Since 'cosine' returns the distance, 1 - distance is used to get similarity similarity_score = 1 - cosine(embedding1, embedding2) return similarity_score def add_dist_score_column( dataframe: pd.DataFrame, sentence: str, ) -> pd.DataFrame: """ Adds a new column to the provided DataFrame with STS (Semantic Textual Similarity) scores, calculated between a given sentence and each question in the 'questions' column of the DataFrame. The DataFrame is then sorted by this new column in descending order and the top 5 rows are returned. Parameters: dataframe (pd.DataFrame): A pandas DataFrame containing a 'questions' column. sentence (str): The sentence against which to compute STS scores for each question in the DataFrame. Returns: pd.DataFrame: A DataFrame containing the original data along with the new 'stsopenai' column, sorted by the 'stsopenai' column, and limited to the top 5 entries with the highest scores. """ # Calculate the STS score between `sentence` and each row's `question` dataframe["stsopenai"] = dataframe["questions"].apply( lambda x: calculate_sts_openai_score(str(x), sentence) ) # Sort the dataframe by the newly added 'stsopenai' column in descending order sorted_dataframe = dataframe.sort_values(by="stsopenai", ascending=False) # Return the top 5 rows from the sorted dataframe return sorted_dataframe.iloc[:5, :] def convert_to_list_of_dict(df: pd.DataFrame) -> List[Dict[str, str]]: """ Reads in a pandas DataFrame and produces a list of dictionaries with two keys each, 'question' and 'answer.' Args: df: A pandas DataFrame with columns named 'questions' and 'answers'. Returns: A list of dictionaries, with each dictionary containing a 'question' and 'answer' key-value pair. """ # Initialize an empty list to store the dictionaries result = [] # Loop through each row of the DataFrame for index, row in df.iterrows(): # Create a dictionary with the current question and answer qa_dict_quest = {"role": "user", "content": row["questions"]} qa_dict_ans = {"role": "assistant", "content": row["answers"]} # Add the dictionary to the result list result.append(qa_dict_quest) result.append(qa_dict_ans) # Return the list of dictionaries return result def query(payload: Dict[str, Any]) -> Dict[str, Any]: """ Sends a JSON payload to a predefined API URL and returns the JSON response. Args: payload (Dict[str, Any]): The JSON payload to be sent to the API. Returns: Dict[str, Any]: The JSON response received from the API. """ # API endpoint URL API_URL = "https://sks7h7h5qkhoxwxo.us-east-1.aws.endpoints.huggingface.cloud" # Headers to indicate both the request and response formats are JSON headers = {"Accept": "application/json", "Content-Type": "application/json"} # Sending a POST request with the JSON payload and headers response = requests.post(API_URL, headers=headers, json=payload) # Returning the JSON response return response.json() def llama2_7b_ysa(prompt: str) -> str: """ Queries a model and retrieves the generated text based on the given prompt. This function sends a prompt to a model (presumably named 'llama2_7b') and extracts the generated text from the model's response. It's tailored for handling responses from a specific API or model query structure where the response is expected to be a list of dictionaries, with at least one dictionary containing a key 'generated_text'. Parameters: - prompt (str): The text prompt to send to the model. Returns: - str: The generated text response from the model. Note: - The function assumes that the 'query' function is previously defined and accessible within the same scope or module. It should send a request to the model and return the response in a structured format. - The 'parameters' dictionary is passed empty but can be customized to include specific request parameters as needed by the model API. """ # Define the query payload with the prompt and any additional parameters query_payload: Dict[str, Any] = { "inputs": prompt, "parameters": {"max_new_tokens": 20}, } # Send the query to the model and store the output response output = query(query_payload) # Extract the 'generated_text' from the first item in the response list response: str = output[0]["generated_text"] return response def quantize_to_4bit(arr: Union[np.ndarray, Any]) -> np.ndarray: """ Converts an array to a 4-bit representation by normalizing and scaling its values. The function first checks if the input is an instance of numpy ndarray, if not, it converts the input into a numpy ndarray. Then, it normalizes the values of the array to be between 0 and 1. Finally, it scales these normalized values to the range of 0-15, corresponding to 4-bit integers, and returns this array of integers. Parameters: arr (Union[np.ndarray, Any]): An array or any type that can be converted to a numpy ndarray. Returns: np.ndarray: A numpy ndarray containing the input data quantized to 4-bit representation. Examples: >>> quantize_to_4bit([0, 128, 255]) array([ 0, 7, 15]) """ if not isinstance(arr, np.ndarray): # Check if the input is a numpy array arr = np.array(arr) # Convert to numpy array if not already arr_min = arr.min() # Find minimum value in the array arr_max = arr.max() # Find maximum value in the array # Normalize array values to a [0, 1] range normalized_arr = (arr - arr_min) / (arr_max - arr_min) # Scale normalized values to a 0-15 range (4-bit) and convert to integer return np.round(normalized_arr * 15).astype(int) def quantized_influence(arr1: np.ndarray, arr2: np.ndarray) -> float: """ Calculates a weighted measure of influence between two arrays based on their quantized (4-bit) versions. This function first quantizes both input arrays to 4-bit representations and then calculates a weighting based on the unique values of the first array's quantized version. It uses these weights to compute local averages within the second array's quantized version, assessing the influence of the first array on the second. The influence is normalized by the standard deviation of the second array's quantized version. Parameters: arr1 (np.ndarray): The first input numpy array. arr2 (np.ndarray): The second input numpy array. Returns: float: The calculated influence value, representing a weighted average that has been normalized. Note: Both inputs must be numpy ndarrays and it's expected that a function named `quantize_to_4bit` exists for converting an array to its 4-bit representation. """ arr1_4bit = quantize_to_4bit(arr1) # Quantize the first array to 4-bit arr2_4bit = quantize_to_4bit(arr2) # Quantize the second array to 4-bit unique_values = np.unique( arr1_4bit ) # Get the unique 4-bit values from the first array y_bar_global = np.mean( arr2_4bit ) # Calculate the global mean of the second array's 4-bit version # Compute the sum of squares of the differences between local and global means, # each weighted by the square of the count of values in the local mean weighted_local_averages = [ (np.mean((arr2_4bit[arr1_4bit == val]) - y_bar_global) ** 2) * len(arr2_4bit[arr1_4bit == val]) ** 2 for val in unique_values ] # Return normalized weighted mean by dividing by the standard deviation of the second array's 4-bit version return np.mean(weighted_local_averages) / np.std(arr2_4bit)