import gradio as gr from huggingface_hub import InferenceClient #STEP 1 FROM SEMANTIC SEARCH from sentence_transformers import SentenceTransformer import torch #STEP 2 FROM SEMANTIC SEARCH # Open the water_cycle.txt file in read mode with UTF-8 encoding with open("/water_cycle.txt", "r", encoding="utf-8") as file: # Read the entire contents of the file and store it in a variable water_cycle_text = file.read() # Print the text below print(water_cycle_text) # Print the text below print(water_cycle_text) #STEP 3 FROM SEMANTIC SEARCH 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_chunk = chunk.strip() if len(cleaned_chunk) > 0: cleaned_chunks.append(cleaned_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(water_cycle_text) # Complete this line #STEP 4 FROM SEMANTIC SEARCH # 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 FROM SEMANTIC SEARCH # 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 = [] # Loop through the top indices and retrieve the corresponding text chunks for index in top_indices: relevant_chunk = text_chunks[index] top_chunks.append(relevant_chunk) # Return the list of most relevant chunks return top_chunks #STEP 6 FROM SEMANTIC SEARCH # Call the get_top_chunks function with the original query top_results = get_top_chunks("How does water get into the sky?", chunk_embedings, cleaned_chunks) # Complete this line # Print the top results print(top_results) client = InferenceClient("HuggingFaceH4/zephyr-7b-beta") def respond(message, history): messages = [{"role": "system", "content": "You are a friendly chatbot"}] if history: messages.extend(history) messages.append ({"role": "user", "content": message}) response = client.chat_completion ( messages, max_tokens=100, temperature=0.2 ) return response['choices'][0]['message']['content'].strip() chatbot = gr.ChatInterface(respond, type="messages") chatbot.launch()