from huggingface_hub import InferenceClient #STEP1FROMSEMANTICSEARCH (import libraries) from sentence_transformers import SentenceTransformer import torch import gradio as gr import random client=InferenceClient("mistralai/Mistral-7B-Instruct-v0.2") #deepseek-ai/DeepSeek-R1-Distill-Qwen-32B # Open the water_cycle.txt file in read mode with UTF-8 encoding - step 2 from semantic search with open("recipes.txt", "r", encoding="utf-8") as file: # Read the entire contents of the file and store it in a variable recipes_text = file.read() # Print the text below print(recipes_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("[END]") # 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: clean = chunk.strip() if len(chunk)>0: cleaned_chunks.append(clean) # 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(recipes_text) # Complete this line #Step 4 # Load the pre-trained embedding model that converts text to vectors model = SentenceTransformer('all-MiniLM-L6-v2') 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(chunk_embeddings.shape) # 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=1).indices # Print the top indices print(top_indices) # Create an empty list to store the most relevant chunks top_chunks = [] # Loop through the top indices and retrieve the corresponding text chunks for i in top_indices: top_chunks.append(text_chunks[i]) print(top_chunks) # Return the list of most relevant chunks return top_chunks def respond(message, selected_options, history,): response = "" best_recipes_chunk = get_top_chunks(message, chunk_embeddings, cleaned_chunks) print(best_recipes_chunk) str_recipes_chunk = "\n".join([str(chunk) for chunk in best_recipes_chunk]) print("RECIPES!!!!!!: " + str_recipes_chunk) messages = [ { "role": "system", "content": ( "You are a helpful recipe assistant. You are only allowed to use the recipes listed below." f"Available Recipes:\n\n{str_recipes_chunk}\n\n(Use ONLY these to answer)" "You must NOT invent or guess any new recipes or ingredients. " "Don't format the recipe as it is in the available recipes. Format your response like this:" "Here is a recipe that matches your needs: [recipe name]. It is [cuisine] cuisine. You can enjoy it for [time of day]. Its main ingredients are [core ingredients]. It fits a [dietary restriction] diet. This dish is [description]. To prepare it: [steps]" "Switch up the format a bit to make sure the responses are varied. Make sure you use proper grammar and don't have random capitals." "If the user’s question doesn’t match any of the recipes exactly or semantically, politely say: " "‘Sorry, I couldn’t find a match. Can you rephrase or ask about another dish?’" ) }, { "role": "user", "content": message }] if history: messages.extend(history) messages.append({"role":"user","content": message}) response = client.chat_completion(messages, max_tokens = 700, temperature = 0.2, top_p = 0.3) #temperature and top_p control randomness return response['choices'][0]['message']['content'].strip() def vote(data: gr.LikeData): if data.liked: print("You upvoted this response: " + data.value["value"]) else: print("You downvoted this response: " + data.value["value"]) with gr.Blocks() as demo: chatbot = gr.Chatbot(label="NutriAssist") chatbot.like(vote, None, None) with gr.Row(): msg = gr.Textbox(placeholder="Ask about an item (e.g., banana peel)", label="Your Question") checkboxes = gr.CheckboxGroup( choices=["Show fun facts", "Explain why", "Summarize rules"], label="Customize your response", ) send_btn = gr.Button("Send") history_state = gr.State([]) send_btn.click( fn=respond, inputs=[msg, checkboxes, history_state], outputs=[chatbot] ) demo.launch() #chatbot = gr.ChatInterface(respond, type="messages") #chatbot.launch()