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| from huggingface_hub import InferenceClient | |
| # Step 1 from the Semantic Search | |
| from sentence_transformers import SentenceTransformer | |
| import torch | |
| import gradio as gr | |
| import random | |
| #beginning of copilot | |
| #end of copilot | |
| # Making requests to the model to generate responses: | |
| client = InferenceClient('Qwen/Qwen2.5-72B-Instruct') | |
| # ============================================ | |
| # Step 2 from the semantic search | |
| # Open the water_cycle.txt file in read mode with UTF-8 encoding | |
| with open("Joy_Scout_info.txt", "r", encoding="utf-8") as file: | |
| # Read the entire contents of the file and store it in a variable | |
| joyscout_info_text = file.read() | |
| # Print the text below | |
| print(joyscout_info_text) | |
| # ============================================= | |
| # Step 3: | |
| def preprocess_text(text): | |
| # Strip extra whitespace from the beginning and the end of the text | |
| cleaned_text = text.strip() | |
| # Split the cleaned_text by every newline character (\n) | |
| chunks = cleaned_text.split("\n") | |
| # Create an empty list to store cleaned chunks | |
| cleaned_chunks = [] | |
| # Write your for-in loop below to clean each chunk and add it to the cleaned_chunks list | |
| for chunk in chunks: | |
| cleaned_chunks.append(chunk) | |
| # Print cleaned_chunks | |
| print(cleaned_chunks) | |
| # Print the length of cleaned_chunks | |
| print(len(cleaned_chunks)) | |
| # Return the cleaned_chunks | |
| return cleaned_chunks | |
| # Call the preprocess_text function and store the result in a cleaned_chunks variable | |
| cleaned_chunks = preprocess_text(joyscout_info_text) # Complete this line | |
| # Load the pre-trained embedding model that converts text to vectors | |
| model = SentenceTransformer('all-MiniLM-L6-v2') | |
| # ============================================ | |
| # Step 4: | |
| def create_embeddings(text_chunks): | |
| # Convert each text chunk into a vector embedding and store as a tensor | |
| chunk_embeddings = model.encode(text_chunks, convert_to_tensor=True) # Replace ... with the text_chunks list | |
| # Print the chunk embeddings | |
| print(chunk_embeddings) | |
| # Print the shape of chunk_embeddings | |
| print(len(chunk_embeddings)) | |
| # Return the chunk_embeddings | |
| return chunk_embeddings | |
| # Call the create_embeddings function and store the result in a new chunk_embeddings variable | |
| chunk_embeddings = create_embeddings(cleaned_chunks) # Complete this line | |
| # ===================================== | |
| # Step 5: | |
| # Define a function to find the most relevant text chunks for a given query, chunk_embeddings, and text_chunks | |
| def get_top_chunks(query, chunk_embeddings, text_chunks): | |
| # Convert the query text into a vector embedding | |
| query_embedding = model.encode(query, convert_to_tensor=True) # Complete this line | |
| # Normalize the query embedding to unit length for accurate similarity comparison | |
| query_embedding_normalized = query_embedding / query_embedding.norm() | |
| # Normalize all chunk embeddings to unit length for consistent comparison | |
| chunk_embeddings_normalized = chunk_embeddings / chunk_embeddings.norm(dim=1, keepdim=True) | |
| # Calculate cosine similarity between query and all chunks using matrix multiplication | |
| similarities = torch.matmul(chunk_embeddings_normalized, query_embedding_normalized) # Complete this line | |
| # Print the similarities | |
| print(similarities) | |
| # Find the indices of the 3 chunks with highest similarity scores | |
| top_indices = torch.topk(similarities, k=3).indices | |
| # Print the top indices | |
| print(top_indices) | |
| # Create an empty list to store the most relevant chunks | |
| top_chunks = [] | |
| # Creating an empty list to now store our most SIMILAR indices | |
| # Loop through the top indices and retrieve the corresponding text chunks | |
| for index in top_indices: # Looping through where our chunks are currently stored and now appending the most similar to be in our new list | |
| top_chunks.append(text_chunks[index]) | |
| # List of the actual chunks needs to be created based on the index values that the top indices list consists of | |
| # Return the list of most relevant chunks | |
| return top_chunks | |
| # ===================================== | |
| # Step 7: Putting data into the dictionary: | |
| # ====================================== | |
| def respond(message, history, hobby_type, age): | |
| best_chunks = get_top_chunks(message, chunk_embeddings, cleaned_chunks) | |
| print(best_chunks) | |
| str_chunks = "/n".join(best_chunks) | |
| messages = [{'role':'system', 'content': f'You are a very kind chatbot giving people hobby suggestions to help them spend less time on their electronic devices. Make sure to be specific to {hobby_type} hobbies and make sure they are appropriate for someone who is {age} years old. You answer their questions based on ' + str_chunks + '.'}] | |
| if history: | |
| messages.extend(history) | |
| messages.append({'role':'user', 'content': message}) | |
| response = client.chat_completion(messages, max_tokens=250, temperature=1.7, top_p=.7) | |
| # Temp and top_p control randomness | |
| return response['choices'][0]['message']['content'].strip() | |
| with gr.Blocks(theme='earneleh/paris') as chatbot: | |
| with gr.Row(scale=1): | |
| with gr.Column(scale=0.7): | |
| hobby_type = gr.CheckboxGroup(['Crafty + DIY', 'Outdoor','Physical', 'Performance + Stage', 'Animal-related'], label = "What category of hobbies are you interested in?") | |
| age = gr.Textbox(label = "How old are you", info = "Enter your age", placeholder = "Type a sentence here...") | |
| gr.Image("ai.png") | |
| with gr.Row(scale=1): | |
| gr.ChatInterface(fn=respond, additional_inputs = [hobby_type, age], type= "messages") | |
| chatbot.launch() |