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FPOC_HDB_Price_Predictor_AI_chat_Assistant

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FPOC_HDB_Price_Predictor_AI_chat_Assistant / app.py

Chia Woon Yap

Update app.py

b5d4882 verified 4 months ago

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	import gradio as gr
	import pandas as pd
	import numpy as np
	import joblib
	import plotly.graph_objects as go
	import plotly.express as px
	from huggingface_hub import hf_hub_download
	import os
	from pathlib import Path
	import warnings
	import os
	warnings.filterwarnings('ignore')
	import re
	from groq import Groq
	import folium
	from folium.plugins import MarkerCluster
	import io
	from fastapi import FastAPI, HTTPException

	app = FastAPI()

	# Initialize Groq client

	groq_api_key = os.getenv("GROQ_API_KEY")
	if groq_api_key:
	#client = Groq(api_key=groq_api_key)
	client = Groq(api_key=groq_api_key) if groq_api_key else None
	else:
	print("⚠️ GROQ_API_KEY not found. Chat functionality will be limited.")
	client = None


	@app.post("/chat")
	async def chat(prompt: str):
	if client is None:
	raise HTTPException(
	status_code=503,
	detail="⚠️ Chat service is unavailable because GROQ_API_KEY is missing."
	)

	try:
	response = client.chat.completions.create(
	model="llama-3.1-8b-instant",
	messages=[{"role": "user", "content": prompt}]
	)
	return {"reply": response.choices[0].message["content"]}
	except Exception as e:
	raise HTTPException(status_code=500, detail=str(e))

	# Try to import xgboost, but fallback to scikit-learn
	try:
	import xgboost as xgb
	XGB_AVAILABLE = True
	print("✅ XGBoost is available")
	except ImportError:
	XGB_AVAILABLE = False
	print("⚠️ XGBoost not available, using scikit-learn models")
	from sklearn.ensemble import RandomForestRegressor

	# Load map data
	try:
	hf_raw_url = 'https://huggingface.co/spaces/Lesterchia174/FPOC_HDB_Price_Predictor_AI_chat_Assistant/resolve/main/Based_Resale_Prices_2025_with_coords.csv'
	map_df = pd.read_csv(hf_raw_url)

	# Convert 'remaining_lease' to a numeric type, converting non-numeric values to NaN
	map_df['remaining_lease'] = pd.to_numeric(map_df['remaining_lease'], errors='coerce')

	# Drop rows where the conversion resulted in NaN
	map_df.dropna(subset=['remaining_lease'], inplace=True)

	# Pre-calculate min/max for Gradio sliders using the 'resale_price' column
	min_lease_val = int(map_df['remaining_lease'].min())
	max_lease_val = int(map_df['remaining_lease'].max())
	min_price_val = int(map_df['resale_price'].min())
	max_price_val = int(map_df['resale_price'].max())

	# Get unique values for dropdowns
	town_options = ['ALL'] + sorted(list(map_df['town'].unique()))
	flat_type_options = ['ALL'] + sorted(list(map_df['flat_type'].unique()))
	flat_model_options = ['ALL'] + sorted(list(map_df['flat_model'].unique()))
	except Exception as e:
	print(f"Error loading the map dataset: {e}")
	map_df = None

	def create_dummy_model(model_type):
	"""Create a realistic dummy model that has all required methods"""
	class RealisticDummyModel:
	def __init__(self, model_type):
	self.model_type = model_type
	self.n_features_in_ = 9
	self.feature_names_in_ = [
	'floor_area_sqm', 'storey_level', 'flat_age', 'remaining_lease',
	'transaction_year', 'flat_type_encoded', 'town_encoded',
	'flat_model_encoded', 'dummy_feature'
	]
	# Add methods that might be called by joblib or other code
	self.get_params = lambda deep=True: {}
	self.set_params = lambda **params: self

	def predict(self, X):
	# Realistic prediction logic
	if isinstance(X, np.ndarray) and len(X.shape) == 2:
	X = X[0] # Take first row if it's a 2D array

	floor_area = X[0]
	storey_level = X[1]
	flat_age = X[2]
	town_encoded = X[6]
	flat_type_encoded = X[5]

	base_price = floor_area * (4800 + town_encoded * 200)
	storey_bonus = storey_level * 2500
	age_discount = flat_age * 1800

	price = base_price + storey_bonus - age_discount + 35000
	if storey_level > 20: price += 15000
	if flat_age < 10: price += 20000

	return np.array([max(300000, price)])

	return RealisticDummyModel(model_type)()

	def safe_joblib_load(filepath):
	"""Safely load joblib file with error handling"""
	try:
	model = joblib.load(filepath)
	print(f"✅ Successfully loaded model from {filepath}")

	# Check if model has required methods
	if not hasattr(model, 'predict'):
	print("❌ Loaded object doesn't have predict method")
	return None

	# Add missing methods if needed
	if not hasattr(model, 'get_params'):
	model.get_params = lambda deep=True: {}
	if not hasattr(model, 'set_params'):
	model.set_params = lambda **params: model

	return model

	except Exception as e:
	print(f"❌ Error loading model from {filepath}: {e}")
	return None

	def load_models():
	"""Load models with robust error handling"""
	models = {}

	# Try to load XGBoost model
	try:
	xgboost_path = hf_hub_download(
	repo_id="Lesterchia174/FPOC_HDB_Price_Predictor_AI_chat_Assistant",
	filename="best_model_xgboost.joblib",
	repo_type="space"
	)
	models['xgboost'] = safe_joblib_load(xgboost_path)
	if models['xgboost'] is None:
	print("⚠️ Creating dummy model for XGBoost")
	models['xgboost'] = create_dummy_model("xgboost")
	else:
	print("✅ XGBoost model loaded and validated")

	except Exception as e:
	print(f"❌ Error downloading XGBoost model: {e}")
	print("⚠️ Creating dummy model for XGBoost")
	models['xgboost'] = create_dummy_model("xgboost")

	return models

	def load_data():
	"""Load data using Hugging Face Hub"""
	try:
	data_path = hf_hub_download(
	repo_id="Lesterchia174/FPOC_HDB_Price_Predictor_AI_chat_Assistant",
	filename="base_hdb_resale_prices_2015Jan-2025Jun_processed.csv",
	repo_type="space"
	)
	df = pd.read_csv(data_path)
	print("✅ Data loaded successfully via Hugging Face Hub")
	return df
	except Exception as e:
	print(f"❌ Error loading data: {e}")
	return create_sample_data()

	def create_sample_data():
	"""Create sample data if real data isn't available"""
	np.random.seed(42)
	towns = ['ANG MO KIO', 'BEDOK', 'TAMPINES', 'WOODLANDS', 'JURONG WEST']
	flat_types = ['4 ROOM', '5 ROOM', 'EXECUTIVE']
	flat_models = ['Improved', 'Model A', 'New Generation']

	data = []
	for _ in range(100):
	town = np.random.choice(towns)
	flat_type = np.random.choice(flat_types)
	flat_model = np.random.choice(flat_models)
	floor_area = np.random.randint(85, 150)
	storey = np.random.randint(1, 25)
	age = np.random.randint(0, 40)

	base_price = floor_area * 5000
	town_bonus = towns.index(town) * 20000
	storey_bonus = storey * 2000
	age_discount = age * 1500
	flat_type_bonus = flat_types.index(flat_type) * 30000

	resale_price = base_price + town_bonus + storey_bonus - age_discount + flat_type_bonus
	resale_price = max(300000, resale_price + np.random.randint(-20000, 20000))

	data.append({
	'town': town, 'flat_type': flat_type, 'flat_model': flat_model,
	'floor_area_sqm': floor_area, 'storey_level': storey,
	'flat_age': age, 'resale_price': resale_price
	})

	return pd.DataFrame(data)

	def preprocess_input(user_input, model_type='xgboost'):
	"""Preprocess user input for prediction with correct feature mapping"""
	# Flat type mapping
	flat_type_mapping = {'1 ROOM': 1, '2 ROOM': 2, '3 ROOM': 3, '4 ROOM': 4,
	'5 ROOM': 5, 'EXECUTIVE': 6, 'MULTI-GENERATION': 7}

	# Town mapping
	town_mapping = {
	'SENGKANG': 0, 'WOODLANDS': 1, 'TAMPINES': 2, 'PUNGGOL': 3,
	'JURONG WEST': 4, 'YISHUN': 5, 'BEDOK': 6, 'HOUGANG': 7,
	'CHOA CHU KANG': 8, 'ANG MO KIO': 9
	}

	# Flat model mapping
	flat_model_mapping = {
	'Model A': 0, 'Improved': 1, 'New Generation': 2,
	'Standard': 3, 'Premium': 4
	}

	# Create input array with features
	input_features = [
	user_input['floor_area_sqm'], # Feature 1
	user_input['storey_level'], # Feature 2
	user_input['flat_age'], # Feature 3
	99 - user_input['flat_age'], # Feature 4: remaining_lease
	2025, # Feature 5: transaction_year
	flat_type_mapping.get(user_input['flat_type'], 4), # Feature 6: flat_type_ordinal
	town_mapping.get(user_input['town'], 0), # Feature 7: town_encoded
	flat_model_mapping.get(user_input['flat_model'], 0), # Feature 8: flat_model_encoded
	1 # Feature 9: (placeholder)
	]

	return np.array([input_features])

	def create_market_insights_chart(data, user_input, predicted_price):
	"""Create market insights visualization"""
	if data is None or len(data) == 0:
	return None

	similar_properties = data[
	(data['flat_type'] == user_input['flat_type']) &
	(data['town'] == user_input['town'])
	]

	if len(similar_properties) < 5:
	similar_properties = data[data['flat_type'] == user_input['flat_type']]

	if len(similar_properties) > 0:
	fig = px.scatter(similar_properties, x='floor_area_sqm', y='resale_price',
	color='flat_model',
	title=f"Market Position: {user_input['flat_type']} in {user_input['town']}",
	labels={'floor_area_sqm': 'Floor Area (sqm)', 'resale_price': 'Resale Price (SGD)'})

	# Add model prediction
	fig.add_trace(go.Scatter(x=[user_input['floor_area_sqm']], y=[predicted_price],
	mode='markers',
	marker=dict(symbol='star', size=20, color='red',
	line=dict(width=2, color='darkred')),
	name='XGBoost Prediction'))

	fig.update_layout(template="plotly_white", height=400, showlegend=True)
	return fig
	return None

	def predict_hdb_price(town, flat_type, flat_model, floor_area_sqm, storey_level, flat_age):
	"""Main prediction function for Gradio with robust error handling"""
	user_input = {
	'town': town,
	'flat_type': flat_type,
	'flat_model': flat_model,
	'floor_area_sqm': floor_area_sqm,
	'storey_level': storey_level,
	'flat_age': flat_age
	}

	try:
	processed_input = preprocess_input(user_input)

	# Get prediction with error handling
	try:
	#predicted_price = max(0, float(models['xgboost'].predict(processed_input)[0]))
	predicted_price = max(100000, float(models['xgboost'].predict(processed_input)))
	except Exception as e:
	print(f"❌ XGBoost prediction error: {e}")
	# Smarter fallback based on area
	predicted_price = max(100000, floor_area_sqm * 5000) # Better fallback calculatio
	#predicted_price = 420000 # Fallback value

	# Create insights
	remaining_lease = 99 - flat_age
	price_per_sqm = predicted_price / floor_area_sqm

	insights = f"""
	Property Summary:
	- Location: {town}
	- Type: {flat_type}
	- Model: {flat_model}
	- Area: {floor_area_sqm} sqm
	- Floor: Level {storey_level}
	- Age: {flat_age} years
	- Remaining Lease: {remaining_lease} years
	- Price per sqm: ${price_per_sqm:,.0f}

	Predicted Price: ${predicted_price:,.0f}

	Financing Eligibility:
	"""

	if remaining_lease >= 60:
	insights += "✅ Bank loan eligible"
	elif remaining_lease >= 20:
	insights += "⚠️ HDB loan eligible only"
	else:
	insights += "❌ Limited financing options"

	# Create chart
	chart = create_market_insights_chart(data, user_input, predicted_price)

	return f"${predicted_price:,.0f}", chart, insights

	except Exception as e:
	error_msg = f"Prediction failed. Error: {str(e)}"
	print(error_msg)
	return "Error: Prediction failed", None, error_msg

	def extract_parameters_from_query(query):
	"""Extract HDB parameters from natural language query using LLM"""
	if not groq_api_key or client is None:
	return {"error": "Please set GROQ_API_KEY environment variable to use chat functionality."}

	try:
	# System prompt to guide the LLM
	system_prompt = """You are an expert at extracting parameters for HDB price prediction from natural language queries.
	Extract the following parameters if mentioned in the query:
	- town (e.g., Ang Mo Kio, Bedok, Tampines)
	- flat_type (e.g., 3 ROOM, 4 ROOM, 5 ROOM, EXECUTIVE)
	- flat_model (e.g., Improved, Model A, New Generation, Standard, Premium)
	- floor_area_sqm (floor area in square meters)
	- storey_level (floor level)
	- flat_age (age of flat in years)

	Return only a JSON object with the extracted parameters. If a parameter is not mentioned, set it to null.
	Example: {"town": "ANG MO KIO", "flat_type": "4 ROOM", "flat_model": "Improved", "floor_area_sqm": 95, "storey_level": 8, "flat_age": 15}"""

	# Query the LLM
	completion = client.chat.completions.create(
	model="llama-3.3-70b-versatile",
	messages=[
	{"role": "system", "content": system_prompt},
	{"role": "user", "content": query}
	],
	temperature=0.5,
	max_tokens=200
	)

	# Extract and parse the JSON response
	response = completion.choices[0].message.content
	# Clean the response to extract just the JSON
	json_match = re.search(r'\{.*\}', response, re.DOTALL)
	if json_match:
	import json
	params = json.loads(json_match.group())
	return params
	else:
	return {"error": "Could not extract parameters from query"}

	except Exception as e:
	return {"error": f"Error processing query: {str(e)}"}

	def is_small_talk(query):
	"""Check if the query is small talk/casual conversation"""
	small_talk_keywords = [
	'hello', 'hi', 'hey', 'good morning', 'good afternoon', 'good evening',
	'how are you', 'how are things', "what's up", 'how do you do',
	'thank you', 'thanks', 'bye', 'goodbye', 'see you', 'nice to meet you',
	'who are you', 'what can you do', 'help', 'tell me about yourself'
	]

	query_lower = query.lower()
	return any(keyword in query_lower for keyword in small_talk_keywords)

	def handle_small_talk(query):
	"""Handle small talk queries with appropriate responses"""
	query_lower = query.lower()

	if any(greeting in query_lower for greeting in ['hello', 'hi', 'hey', 'good morning', 'good afternoon', 'good evening']):
	return "Hello! 👋 I'm your HDB price assistant. How can I help you today?"

	elif any(how_are_you in query_lower for how_are_you in ['how are you', 'how are things', "what's up", 'how do you do']):
	return "I'm doing great, thanks for asking! I'm here to help you with HDB price predictions and information. What can I assist you with today?"

	elif any(thanks in query_lower for thanks in ['thank you', 'thanks']):
	return "You're welcome! 😊 Is there anything else you'd like to know about HDB prices?"

	elif any(bye in query_lower for bye in ['bye', 'goodbye', 'see you']):
	return "Goodbye! 👋 Feel free to come back if you have more questions about HDB prices!"

	elif 'who are you' in query_lower:
	return "I'm an AI assistant specialized in helping with HDB resale price predictions and information. I can estimate property values based on various factors like location, flat type, size, and age."

	elif 'what can you do' in query_lower or 'help' in query_lower:
	return "I can help you with:\n- Predicting HDB resale prices\n- Answering questions about HDB properties\n- Providing market insights\n\nJust tell me about the property you're interested in (location, type, size, etc.) and I'll give you an estimate!"

	elif 'tell me about yourself' in query_lower:
	return "I'm an AI assistant powered by machine learning models trained on HDB resale data. I can provide price estimates and insights about public housing in Singapore. My goal is to help you make informed decisions about HDB properties!"

	else:
	return "I'm here to help with HDB price predictions and information. How can I assist you today?"

	def answer_general_hdb_question(query, chat_history):
	"""Answer general HDB questions using the LLM"""
	if not groq_api_key or client is None:
	return "Please set GROQ_API_KEY environment variable to use chat functionality.", chat_history

	try:
	completion = client.chat.completions.create(
	model="llama-3.3-70b-versatile",
	messages=[
	{
	"role": "system",
	"content": "You are a helpful assistant specialized in HDB (Housing & Development Board) properties in Singapore. Provide accurate, helpful information about HDB prices, policies, and market trends."
	},
	{
	"role": "user",
	"content": f"Answer this question about HDB: {query}"
	}
	],
	temperature=0.3,
	max_tokens=500
	)
	response = completion.choices[0].message.content
	chat_history.append((query, response))
	return response, chat_history
	except Exception as e:
	error_msg = f"I encountered an error. Please try again later."
	chat_history.append((query, error_msg))
	return error_msg, chat_history

	def chat_with_llm(query, chat_history):
	"""Handle chat queries about HDB pricing and small talk"""
	if not groq_api_key or client is None:
	return "Please set GROQ_API_KEY...", chat_history

	# 1. First, check for small talk
	if is_small_talk(query):
	response = handle_small_talk(query)
	chat_history.append((query, response))
	return response, chat_history

	# 2. Check if the query is a clear request for a general explanation/trend (not a specific price)
	is_general_query = any(keyword in query.lower() for keyword in [
	'trend', 'overview', 'how are', 'what are', 'like in', 'average',
	'over the years', 'market', 'compare'
	])

	# 3. If it's a general query, use the LLM to answer it directly
	if is_general_query:
	try:
	completion = client.chat.completions.create(
	model="llama-3.3-70b-versatile",
	messages=[
	{
	"role": "system",
	"content": "You are a helpful assistant specialized in HDB (Housing & Development Board) properties in Singapore. Provide accurate, helpful information about HDB prices, policies, and market trends. Use the provided context if available."
	},
	{
	"role": "user",
	"content": f"Based on general HDB market knowledge, answer this question: {query}"
	}
	],
	temperature=0.3,
	max_tokens=500
	)
	response = completion.choices[0].message.content
	chat_history.append((query, response))
	return response, chat_history
	except Exception as e:
	error_msg = f"I encountered an error. Please try again later."
	chat_history.append((query, error_msg))
	return error_msg, chat_history

	# 4. If it's not clearly general, try to extract parameters for a specific prediction
	params = extract_parameters_from_query(query)

	if "error" in params:
	# If extraction failed, fall back to general Q&A
	return answer_general_hdb_question(query, chat_history)

	# 5. Check what we got back from parameter extraction
	extracted_params = {k: v for k, v in params.items() if v is not None}
	required_for_prediction = ['town', 'flat_type', 'floor_area_sqm', 'storey_level', 'flat_age']

	# 6. If the user only provided a town or one other parameter, it's likely a general question.
	if len(extracted_params) < 3: # e.g., if only 'town' and 'flat_type' are provided
	# Ask a clarifying question or provide a general overview
	if 'town' in extracted_params:
	town = extracted_params['town']
	# You could add a pre-generated fact here, e.g., average price for that town from the dataset
	response = f"You asked about {town}. HDB prices can vary widely based on flat type, size, age, and specific location within the town. "
	response += f"For example, are you interested in 4-Room or 5-Room flats? What's your budget or preferred size? "
	response += "Alternatively, I can give you a prediction if you provide more details like flat type, size, and age."
	else:
	response = "I specialize in HDB price predictions and information. Could you provide more details about the property you're interested in (e.g., town, flat type, size) so I can give you a accurate estimate or information?"
	chat_history.append((query, response))
	return response, chat_history

	# 7. If we have most parameters, ask for the missing ones specifically
	missing_params = [param for param in required_for_prediction if params.get(param) is None]
	if missing_params:
	missing_list = ", ".join(missing_params)
	response = f"I'd be happy to predict a price for you. I just need a few more details: {missing_list}."
	chat_history.append((query, response))
	return response, chat_history

	# 8. If we have all parameters, make a prediction!
	try:
	# Convert string numbers to appropriate types
	if isinstance(params['floor_area_sqm'], str):
	params['floor_area_sqm'] = float(params['floor_area_sqm'])
	if isinstance(params['storey_level'], str):
	params['storey_level'] = int(params['storey_level'])
	if isinstance(params['flat_age'], str):
	params['flat_age'] = int(params['flat_age'])

	# Make prediction
	price, chart, insights = predict_hdb_price(
	params['town'], params['flat_type'], params['flat_model'],
	params['floor_area_sqm'], params['storey_level'], params['flat_age']
	)

	# Format response
	response = f"Based on your query:\n\n"
	response += f"📍 Town: {params['town']}\n"
	response += f"🏠 Flat Type: {params['flat_type']}\n"
	response += f"📐 Floor Area: {params['floor_area_sqm']} sqm\n"
	response += f"🏢 Storey Level: {params['storey_level']}\n"
	response += f"📅 Flat Age: {params['flat_age']} years\n\n"
	response += f"💰 Predicted Price: {price}\n\n"
	response += insights

	chat_history.append((query, response))
	return response, chat_history

	except Exception as e:
	error_msg = f"Error making prediction: {str(e)}"
	chat_history.append((query, error_msg))
	return error_msg, chat_history

	def generate_map_and_stats(filter_town, filter_flat_type, filter_flat_model,
	min_lease, max_lease, min_price, max_price):
	"""Create the Singapore map and generate summary stats"""
	if map_df is None:
	return "<p align='center'>Dataset not found. Please ensure the URL is correct and the file exists.</p>", ""

	# Apply filters
	filtered_df = map_df.copy()

	if filter_town and filter_town != 'ALL':
	filtered_df = filtered_df[filtered_df['town'] == filter_town]

	if filter_flat_type and filter_flat_type != 'ALL':
	filtered_df = filtered_df[filtered_df['flat_type'] == filter_flat_type]

	if filter_flat_model and filter_flat_model != 'ALL':
	filtered_df = filtered_df[filtered_df['flat_model'] == filter_flat_model]

	# Filter based on lease and price sliders using 'resale_price'
	filtered_df = filtered_df[(filtered_df['remaining_lease'] >= min_lease) &
	(filtered_df['remaining_lease'] <= max_lease)]
	filtered_df = filtered_df[(filtered_df['resale_price'] >= min_price) &
	(filtered_df['resale_price'] <= max_price)]

	# Handle case with no matching records
	if len(filtered_df) == 0:
	return "<p align='center'>No data available with the selected filters.</p>", "No data available with the selected filters."

	# Create base map centered on Singapore
	singapore_coords = [1.3521, 103.8198] # Approximate center of Singapore
	m = folium.Map(location=singapore_coords, zoom_start=11, tiles='OpenStreetMap')

	# Create marker cluster
	marker_cluster = MarkerCluster().add_to(m)

	# Create a Folium linear colormap using 'resale_price'
	folium_colormap = folium.LinearColormap(['green', 'yellow', 'red'],
	vmin=filtered_df['resale_price'].min(),
	vmax=filtered_df['resale_price'].max())
	folium_colormap.caption = 'Resale Price (SGD)'
	m.add_child(folium_colormap)

	# Add markers for each property
	for idx, row in filtered_df.iterrows():
	# Get color based on 'resale_price'
	color = folium_colormap(row['resale_price'])

	popup_content = f"""
	<b>Town:</b> {row['town']}<br>
	<b>Flat Type:</b> {row['flat_type']}<br>
	<b>Flat Model:</b> {row['flat_model']}<br>
	<b>Address:</b> {row['full_address']}<br>
	<b>Floor Area:</b> {row['floor_area_sqm']} sqm<br>
	<b>Remaining Lease:</b> {row['remaining_lease']} years<br>
	<b>Storey:</b> {row['storey_range']}<br>
	<b>Resale Price:</b> ${row['resale_price']:,.0f}<br>
	<b>Transaction Date:</b> {row['month']}
	"""

	folium.CircleMarker(
	location=[row['latitude'], row['longitude']],
	radius=5,
	popup=folium.Popup(popup_content, max_width=300),
	color=color,
	fill=True,
	fillColor=color,
	fillOpacity=0.7,
	weight=1
	).add_to(marker_cluster)

	# Convert map to HTML string
	map_html = m._repr_html_()

	# Generate summary statistics as a markdown string using 'resale_price'
	stats_string = f"""
	### Summary Statistics
	- Total Records: {len(filtered_df):,}
	- Average Price [inc Outlier]: ${filtered_df['resale_price'].mean():,.0f}
	- Median Price [exc Outlier]: ${filtered_df['resale_price'].median():,.0f}
	- Minimum Price: ${filtered_df['resale_price'].min():,.0f}
	- Maximum Price: ${filtered_df['resale_price'].max():,.0f}
	- Average Remaining Lease: {filtered_df['remaining_lease'].mean():.1f} years
	- Median Remaining Lease: {filtered_df['remaining_lease'].median():.1f} years
	"""

	return map_html, stats_string

	# Preload models and data
	print("Loading models and data...")
	models = load_models()
	data = load_data()

	# Define Gradio interface
	towns_list = [
	'SENGKANG', 'WOODLANDS', 'TAMPINES', 'PUNGGOL', 'JURONG WEST',
	'YISHUN', 'BEDOK', 'HOUGANG', 'CHOA CHU KANG', 'ANG MO KIO'
	]

	flat_types = ['3 ROOM', '4 ROOM', '5 ROOM', 'EXECUTIVE', '2 ROOM', '1 ROOM']
	flat_models = ['Model A', 'Improved', 'New Generation', 'Standard', 'Premium']

	# Create Gradio interface with chatbot
	with gr.Blocks(title="🏠 HDB Price Predictor + Chat + Map", theme=gr.themes.Soft()) as demo:
	gr.Markdown("# 🏠 HDB Price Predictor + AI Chat + Interactive Map")
	gr.Markdown("Predict HDB resale prices using XGBoost model, chat with our AI assistant, or explore properties on an interactive map")

	with gr.Tab("Traditional Interface"):
	with gr.Row():
	with gr.Column():
	town = gr.Dropdown(label="Town", choices=sorted(towns_list), value="ANG MO KIO")
	flat_type = gr.Dropdown(label="Flat Type", choices=sorted(flat_types), value="4 ROOM")
	flat_model = gr.Dropdown(label="Flat Model", choices=sorted(flat_models), value="Improved")
	floor_area_sqm = gr.Slider(label="Floor Area (sqm)", minimum=30, maximum=200, value=95, step=5)
	storey_level = gr.Slider(label="Storey Level", minimum=1, maximum=50, value=8, step=1)
	flat_age = gr.Slider(label="Flat Age (years)", minimum=0, maximum=99, value=15, step=1)

	predict_btn = gr.Button("🔮 Predict Price", variant="primary")

	with gr.Column():
	predicted_price = gr.Label(label="💰 Predicted Price")
	insights = gr.Markdown(label="📋 Property Summary")

	with gr.Row():
	chart_output = gr.Plot(label="📈 Market Insights")

	# Connect button to function
	predict_btn.click(
	fn=predict_hdb_price,
	inputs=[town, flat_type, flat_model, floor_area_sqm, storey_level, flat_age],
	outputs=[predicted_price, chart_output, insights]
	)

	with gr.Tab("AI Chat Assistant"):
	gr.Markdown("💬 Chat with our AI assistant to get HDB price predictions using natural language!")
	gr.Markdown("Example: 'What would be the price of a 4-room model A flat in Ang Mo Kio with 95 sqm, on the 8th floor, that's 15 years old?'")
	gr.Markdown("You can also say hello, ask how I am, or ask general questions about HDB!")

	chatbot = gr.Chatbot(label="HDB Price Chatbot", height=500)
	msg = gr.Textbox(label="Your question", placeholder="Type your message here...")
	clear = gr.Button("Clear Chat")

	def respond(message, chat_history):
	response, updated_history = chat_with_llm(message, chat_history)
	return updated_history

	msg.submit(respond, [msg, chatbot], [chatbot])
	clear.click(lambda: None, None, [chatbot], queue=False)

	with gr.Tab("Interactive Map"):
	gr.Markdown("# 🗺️ Singapore HDB Resale Prices Map")
	gr.Markdown("An interactive map to visualize and filter HDB flat prices across Singapore.")

	with gr.Row():
	with gr.Column(scale=1):
	town_input = gr.Dropdown(choices=town_options, label="Select Town", value="ALL")
	flat_type_input = gr.Dropdown(choices=flat_type_options, label="Select Flat Type", value="ALL")
	flat_model_input = gr.Dropdown(choices=flat_model_options, label="Select Flat Model", value="ALL")

	gr.Markdown("### Filter by Lease and Price")
	min_lease_input = gr.Slider(minimum=min_lease_val, maximum=max_lease_val,
	value=min_lease_val, step=1, label="Min Remaining Lease (years)")
	max_lease_input = gr.Slider(minimum=min_lease_val, maximum=max_lease_val,
	value=max_lease_val, step=1, label="Max Remaining Lease (years)")
	min_price_input = gr.Slider(minimum=min_price_val, maximum=max_price_val,
	value=min_price_val, step=1000, label="Min Price (SGD)")
	max_price_input = gr.Slider(minimum=min_price_val, maximum=max_price_val,
	value=max_price_val, step=1000, label="Max Price (SGD)")

	# Add a button to generate the result
	generate_button = gr.Button("Generate Results", variant="primary")

	with gr.Column(scale=2):
	map_output = gr.HTML(label="Interactive Map")
	stats_output = gr.Markdown(label="Summary Statistics")
	gr.Markdown("""
	---
	### Map Color Legend
	The colors of the markers on the map represent the resale price of the HDB flats:

	- <span style='color:green;'>Green</span>: Indicates a lower resale price.
	- <span style='color:yellow;'>Yellow</span>: Indicates a mid-range resale price.
	- <span style='color:red;'>Red</span>: Indicates a higher resale price.
	""")

	# Link the button click to the function
	inputs = [town_input, flat_type_input, flat_model_input,
	min_lease_input, max_lease_input, min_price_input, max_price_input]

	generate_button.click(
	fn=generate_map_and_stats,
	inputs=inputs,
	outputs=[map_output, stats_output]
	)

	# To run in Colab
	if __name__ == "__main__":
	demo.launch()
	warnings.filterwarnings('ignore')
	import re
	from groq import Groq

	# Initialize Groq client
	groq_api_key = os.getenv("GROQ_API_KEY")
	if groq_api_key:
	client = Groq(api_key=groq_api_key)
	else:
	print("⚠️ GROQ_API_KEY not found. Chat functionality will be limited.")
	client = None

	# Try to import xgboost, but fallback to scikit-learn
	try:
	import xgboost as xgb
	XGB_AVAILABLE = True
	print("✅ XGBoost is available")
	except ImportError:
	XGB_AVAILABLE = False
	print("⚠️ XGBoost not available, using scikit-learn models")
	from sklearn.ensemble import RandomForestRegressor

	def create_dummy_model(model_type):
	"""Create a realistic dummy model that has all required methods"""
	class RealisticDummyModel:
	def __init__(self, model_type):
	self.model_type = model_type
	self.n_features_in_ = 9
	self.feature_names_in_ = [
	'floor_area_sqm', 'storey_level', 'flat_age', 'remaining_lease',
	'transaction_year', 'flat_type_encoded', 'town_encoded',
	'flat_model_encoded', 'dummy_feature'
	]
	# Add methods that might be called by joblib or other code
	self.get_params = lambda deep=True: {}
	self.set_params = lambda **params: self

	def predict(self, X):
	# Realistic prediction logic
	if isinstance(X, np.ndarray) and len(X.shape) == 2:
	X = X[0] # Take first row if it's a 2D array

	floor_area = X[0]
	storey_level = X[1]
	flat_age = X[2]
	town_encoded = X[6]
	flat_type_encoded = X[5]

	base_price = floor_area * (4800 + town_encoded * 200)
	storey_bonus = storey_level * 2500
	age_discount = flat_age * 1800

	price = base_price + storey_bonus - age_discount + 35000
	if storey_level > 20: price += 15000
	if flat_age < 10: price += 20000

	return np.array([max(300000, price)])

	return RealisticDummyModel(model_type)()

	def safe_joblib_load(filepath):
	"""Safely load joblib file with error handling"""
	try:
	model = joblib.load(filepath)
	print(f"✅ Successfully loaded model from {filepath}")

	# Check if model has required methods
	if not hasattr(model, 'predict'):
	print("❌ Loaded object doesn't have predict method")
	return None

	# Add missing methods if needed
	if not hasattr(model, 'get_params'):
	model.get_params = lambda deep=True: {}
	if not hasattr(model, 'set_params'):
	model.set_params = lambda **params: model

	return model

	except Exception as e:
	print(f"❌ Error loading model from {filepath}: {e}")
	return None

	def load_models():
	"""Load models with robust error handling"""
	models = {}

	# Try to load XGBoost model
	try:
	xgboost_path = hf_hub_download(
	repo_id="Lesterchia174/HDB_Price_Predictor",
	filename="best_model_xgboost.joblib",
	repo_type="space"
	)
	models['xgboost'] = safe_joblib_load(xgboost_path)
	if models['xgboost'] is None:
	print("⚠️ Creating dummy model for XGBoost")
	models['xgboost'] = create_dummy_model("xgboost")
	else:
	print("✅ XGBoost model loaded and validated")

	except Exception as e:
	print(f"❌ Error downloading XGBoost model: {e}")
	print("⚠️ Creating dummy model for XGBoost")
	models['xgboost'] = create_dummy_model("xgboost")

	return models

	def load_data():
	"""Load data using Hugging Face Hub"""
	try:
	data_path = hf_hub_download(
	repo_id="Lesterchia174/HDB_Price_Predictor",
	filename="base_hdb_resale_prices_2015Jan-2025Jun_processed.csv",
	repo_type="space"
	)
	df = pd.read_csv(data_path)
	print("✅ Data loaded successfully via Hugging Face Hub")
	return df
	except Exception as e:
	print(f"❌ Error loading data: {e}")
	return create_sample_data()

	def create_sample_data():
	"""Create sample data if real data isn't available"""
	np.random.seed(42)
	towns = ['ANG MO KIO', 'BEDOK', 'TAMPINES', 'WOODLANDS', 'JURONG WEST']
	flat_types = ['4 ROOM', '5 ROOM', 'EXECUTIVE']
	flat_models = ['Improved', 'Model A', 'New Generation']

	data = []
	for _ in range(100):
	town = np.random.choice(towns)
	flat_type = np.random.choice(flat_types)
	flat_model = np.random.choice(flat_models)
	floor_area = np.random.randint(85, 150)
	storey = np.random.randint(1, 25)
	age = np.random.randint(0, 40)

	base_price = floor_area * 5000
	town_bonus = towns.index(town) * 20000
	storey_bonus = storey * 2000
	age_discount = age * 1500
	flat_type_bonus = flat_types.index(flat_type) * 30000

	resale_price = base_price + town_bonus + storey_bonus - age_discount + flat_type_bonus
	resale_price = max(300000, resale_price + np.random.randint(-20000, 20000))

	data.append({
	'town': town, 'flat_type': flat_type, 'flat_model': flat_model,
	'floor_area_sqm': floor_area, 'storey_level': storey,
	'flat_age': age, 'resale_price': resale_price
	})

	return pd.DataFrame(data)

	def preprocess_input(user_input, model_type='xgboost'):
	"""Preprocess user input for prediction with correct feature mapping"""
	# Flat type mapping
	flat_type_mapping = {'1 ROOM': 1, '2 ROOM': 2, '3 ROOM': 3, '4 ROOM': 4,
	'5 ROOM': 5, 'EXECUTIVE': 6, 'MULTI-GENERATION': 7}

	# Town mapping
	town_mapping = {
	'SENGKANG': 0, 'WOODLANDS': 1, 'TAMPINES': 2, 'PUNGGOL': 3,
	'JURONG WEST': 4, 'YISHUN': 5, 'BEDOK': 6, 'HOUGANG': 7,
	'CHOA CHU KANG': 8, 'ANG MO KIO': 9
	}

	# Flat model mapping
	flat_model_mapping = {
	'Model A': 0, 'Improved': 1, 'New Generation': 2,
	'Standard': 3, 'Premium': 4
	}

	# Create input array with features
	input_features = [
	user_input['floor_area_sqm'], # Feature 1
	user_input['storey_level'], # Feature 2
	user_input['flat_age'], # Feature 3
	99 - user_input['flat_age'], # Feature 4: remaining_lease
	2025, # Feature 5: transaction_year
	flat_type_mapping.get(user_input['flat_type'], 4), # Feature 6: flat_type_ordinal
	town_mapping.get(user_input['town'], 0), # Feature 7: town_encoded
	flat_model_mapping.get(user_input['flat_model'], 0), # Feature 8: flat_model_encoded
	1 # Feature 9: (placeholder)
	]

	return np.array([input_features])

	def create_market_insights_chart(data, user_input, predicted_price):
	"""Create market insights visualization"""
	if data is None or len(data) == 0:
	return None

	similar_properties = data[
	(data['flat_type'] == user_input['flat_type']) &
	(data['town'] == user_input['town'])
	]

	if len(similar_properties) < 5:
	similar_properties = data[data['flat_type'] == user_input['flat_type']]

	if len(similar_properties) > 0:
	fig = px.scatter(similar_properties, x='floor_area_sqm', y='resale_price',
	color='flat_model',
	title=f"Market Position: {user_input['flat_type']} in {user_input['town']}",
	labels={'floor_area_sqm': 'Floor Area (sqm)', 'resale_price': 'Resale Price (SGD)'})

	# Add model prediction
	fig.add_trace(go.Scatter(x=[user_input['floor_area_sqm']], y=[predicted_price],
	mode='markers',
	marker=dict(symbol='star', size=20, color='red',
	line=dict(width=2, color='darkred')),
	name='XGBoost Prediction'))

	fig.update_layout(template="plotly_white", height=400, showlegend=True)
	return fig
	return None

	def predict_hdb_price(town, flat_type, flat_model, floor_area_sqm, storey_level, flat_age):
	"""Main prediction function for Gradio with robust error handling"""
	user_input = {
	'town': town,
	'flat_type': flat_type,
	'flat_model': flat_model,
	'floor_area_sqm': floor_area_sqm,
	'storey_level': storey_level,
	'flat_age': flat_age
	}

	try:
	processed_input = preprocess_input(user_input)

	# Get prediction with error handling
	try:
	predicted_price = max(0, float(models['xgboost'].predict(processed_input)[0]))
	except Exception as e:
	print(f"❌ XGBoost prediction error: {e}")
	predicted_price = 400000 # Fallback value

	# Create insights
	remaining_lease = 99 - flat_age
	price_per_sqm = predicted_price / floor_area_sqm

	insights = f"""
	Property Summary:
	- Location: {town}
	- Type: {flat_type}
	- Model: {flat_model}
	- Area: {floor_area_sqm} sqm
	- Floor: Level {storey_level}
	- Age: {flat_age} years
	- Remaining Lease: {remaining_lease} years
	- Price per sqm: ${price_per_sqm:,.0f}

	Predicted Price: ${predicted_price:,.0f}

	Financing Eligibility:
	"""

	if remaining_lease >= 60:
	insights += "✅ Bank loan eligible"
	elif remaining_lease >= 20:
	insights += "⚠️ HDB loan eligible only"
	else:
	insights += "❌ Limited financing options"

	# Create chart
	chart = create_market_insights_chart(data, user_input, predicted_price)

	return f"${predicted_price:,.0f}", chart, insights

	except Exception as e:
	error_msg = f"Prediction failed. Error: {str(e)}"
	print(error_msg)
	return "Error: Prediction failed", None, error_msg

	def extract_parameters_from_query(query):
	"""Extract HDB parameters from natural language query using LLM"""
	if not groq_api_key or client is None:
	return {"error": "Please set GROQ_API_KEY environment variable to use chat functionality."}

	try:
	# System prompt to guide the LLM
	system_prompt = """You are an expert at extracting parameters for HDB price prediction from natural language queries.
	Extract the following parameters if mentioned in the query:
	- town (e.g., Ang Mo Kio, Bedok, Tampines)
	- flat_type (e.g., 3 ROOM, 4 ROOM, 5 ROOM, EXECUTIVE)
	- flat_model (e.g., Improved, Model A, New Generation, Standard, Premium)
	- floor_area_sqm (floor area in square meters)
	- storey_level (floor level)
	- flat_age (age of flat in years)

	Return only a JSON object with the extracted parameters. If a parameter is not mentioned, set it to null.
	Example: {"town": "ANG MO KIO", "flat_type": "4 ROOM", "flat_model": "Improved", "floor_area_sqm": 95, "storey_level": 8, "flat_age": 15}"""

	# Query the LLM
	completion = client.chat.completions.create(
	model="llama-3.3-70b-versatile",
	messages=[
	{"role": "system", "content": system_prompt},
	{"role": "user", "content": query}
	],
	temperature=0.1,
	max_tokens=200
	)

	# Extract and parse the JSON response
	response = completion.choices[0].message.content
	# Clean the response to extract just the JSON
	json_match = re.search(r'\{.*\}', response, re.DOTALL)
	if json_match:
	import json
	params = json.loads(json_match.group())
	return params
	else:
	return {"error": "Could not extract parameters from query"}

	except Exception as e:
	return {"error": f"Error processing query: {str(e)}"}

	def is_small_talk(query):
	"""Check if the query is small talk/casual conversation"""
	small_talk_keywords = [
	'hello', 'hi', 'hey', 'good morning', 'good afternoon', 'good evening',
	'how are you', 'how are things', "what's up", 'how do you do',
	'thank you', 'thanks', 'bye', 'goodbye', 'see you', 'nice to meet you',
	'who are you', 'what can you do', 'help', 'tell me about yourself'
	]

	query_lower = query.lower()
	return any(keyword in query_lower for keyword in small_talk_keywords)

	def handle_small_talk(query):
	"""Handle small talk queries with appropriate responses"""
	query_lower = query.lower()

	if any(greeting in query_lower for greeting in ['hello', 'hi', 'hey', 'good morning', 'good afternoon', 'good evening']):
	return "Hello! 👋 I'm your HDB price assistant. How can I help you today?"

	elif any(how_are_you in query_lower for how_are_you in ['how are you', 'how are things', "what's up", 'how do you do']):
	return "I'm doing great, thanks for asking! I'm here to help you with HDB price predictions and information. What can I assist you with today?"

	elif any(thanks in query_lower for thanks in ['thank you', 'thanks']):
	return "You're welcome! 😊 Is there anything else you'd like to know about HDB prices?"

	elif any(bye in query_lower for bye in ['bye', 'goodbye', 'see you']):
	return "Goodbye! 👋 Feel free to come back if you have more questions about HDB prices!"

	elif 'who are you' in query_lower:
	return "I'm an AI assistant specialized in helping with HDB resale price predictions and information. I can estimate property values based on various factors like location, flat type, size, and age."

	elif 'what can you do' in query_lower or 'help' in query_lower:
	return "I can help you with:\n- Predicting HDB resale prices\n- Answering questions about HDB properties\n- Providing market insights\n\nJust tell me about the property you're interested in (location, type, size, etc.) and I'll give you an estimate!"

	elif 'tell me about yourself' in query_lower:
	return "I'm an AI assistant powered by machine learning models trained on HDB resale data. I can provide price estimates and insights about public housing in Singapore. My goal is to help you make informed decisions about HDB properties!"

	else:
	return "I'm here to help with HDB price predictions and information. How can I assist you today?"


	def chat_with_llm(query, chat_history):
	"""Handle chat queries about HDB pricing and small talk"""
	if not groq_api_key or client is None:
	return "Please set GROQ_API_KEY...", chat_history

	# 1. First, check for small talk
	if is_small_talk(query):
	response = handle_small_talk(query)
	chat_history.append((query, response))
	return response, chat_history

	# 2. Check if the query is a clear request for a general explanation/trend (not a specific price)
	is_general_query = any(keyword in query.lower() for keyword in [
	'trend', 'overview', 'how are', 'what are', 'like in', 'average',
	'over the years', 'market', 'compare'
	])

	# 3. If it's a general query, use the LLM to answer it directly
	if is_general_query:
	try:
	completion = client.chat.completions.create(
	model="llama-3.3-70b-versatile",
	messages=[
	{
	"role": "system",
	"content": "You are a helpful assistant specialized in HDB (Housing & Development Board) properties in Singapore. Provide accurate, helpful information about HDB prices, policies, and market trends. Use the provided context if available."
	},
	{
	"role": "user",
	"content": f"Based on general HDB market knowledge, answer this question: {query}"
	}
	],
	temperature=0.3,
	max_tokens=500
	)
	response = completion.choices[0].message.content
	chat_history.append((query, response))
	return response, chat_history
	except Exception as e:
	error_msg = f"I encountered an error. Please try again later."
	chat_history.append((query, error_msg))
	return error_msg, chat_history

	# 4. If it's not clearly general, try to extract parameters for a specific prediction
	params = extract_parameters_from_query(query)

	if "error" in params:
	# If extraction failed, fall back to general Q&A
	return answer_general_hdb_question(query, chat_history)

	# 5. Check what we got back from parameter extraction
	extracted_params = {k: v for k, v in params.items() if v is not None}
	required_for_prediction = ['town', 'flat_type', 'floor_area_sqm', 'storey_level', 'flat_age']

	# 6. If the user only provided a town or one other parameter, it's likely a general question.
	if len(extracted_params) < 3: # e.g., if only 'town' and 'flat_type' are provided
	# Ask a clarifying question or provide a general overview
	if 'town' in extracted_params:
	town = extracted_params['town']
	# You could add a pre-generated fact here, e.g., average price for that town from the dataset
	response = f"You asked about {town}. HDB prices can vary widely based on flat type, size, age, and specific location within the town. "
	response += f"For example, are you interested in 4-Room or 5-Room flats? What's your budget or preferred size? "
	response += "Alternatively, I can give you a prediction if you provide more details like flat type, size, and age."
	else:
	response = "I specialize in HDB price predictions and information. Could you provide more details about the property you're interested in (e.g., town, flat type, size) so I can give you a accurate estimate or information?"
	chat_history.append((query, response))
	return response, chat_history

	# 7. If we have most parameters, ask for the missing ones specifically
	missing_params = [param for param in required_for_prediction if params.get(param) is None]
	if missing_params:
	missing_list = ", ".join(missing_params)
	response = f"I'd be happy to predict a price for you. I just need a few more details: {missing_list}."
	chat_history.append((query, response))
	return response, chat_history

	# 8. If we have all parameters, make the prediction!
	# ... (rest of the prediction code remains the same)



	# If we have all parameters, make a prediction
	try:
	# Convert string numbers to appropriate types
	if isinstance(params['floor_area_sqm'], str):
	params['floor_area_sqm'] = float(params['floor_area_sqm'])
	if isinstance(params['storey_level'], str):
	params['storey_level'] = int(params['storey_level'])
	if isinstance(params['flat_age'], str):
	params['flat_age'] = int(params['flat_age'])

	# Make prediction
	price, chart, insights = predict_hdb_price(
	params['town'], params['flat_type'], params['flat_model'],
	params['floor_area_sqm'], params['storey_level'], params['flat_age']
	)

	# Format response
	response = f"Based on your query:\n\n"
	response += f"📍 Town: {params['town']}\n"
	response += f"🏠 Flat Type: {params['flat_type']}\n"
	response += f"📐 Floor Area: {params['floor_area_sqm']} sqm\n"
	response += f"🏢 Storey Level: {params['storey_level']}\n"
	response += f"📅 Flat Age: {params['flat_age']} years\n\n"
	response += f"💰 Predicted Price: {price}\n\n"
	response += insights

	chat_history.append((query, response))
	return response, chat_history

	except Exception as e:
	error_msg = f"Error making prediction: {str(e)}"
	chat_history.append((query, error_msg))
	return error_msg, chat_history

	# Preload models and data
	print("Loading models and data...")
	models = load_models()
	data = load_data()

	# Define Gradio interface
	towns_list = [
	'SENGKANG', 'WOODLANDS', 'TAMPINES', 'PUNGGOL', 'JURONG WEST',
	'YISHUN', 'BEDOK', 'HOUGANG', 'CHOA CHU KANG', 'ANG MO KIO'
	]

	flat_types = ['3 ROOM', '4 ROOM', '5 ROOM', 'EXECUTIVE', '2 ROOM', '1 ROOM']
	flat_models = ['Model A', 'Improved', 'New Generation', 'Standard', 'Premium']

	# Create Gradio interface with chatbot
	with gr.Blocks(title="🏠 HDB Price Predictor + Chat", theme=gr.themes.Soft()) as demo:
	gr.Markdown("# 🏠 HDB Price Predictor + AI Chat")
	gr.Markdown("Predict HDB resale prices using XGBoost model or chat with our AI assistant")

	with gr.Tab("Traditional Interface"):
	with gr.Row():
	with gr.Column():
	town = gr.Dropdown(label="Town", choices=sorted(towns_list), value="ANG MO KIO")
	flat_type = gr.Dropdown(label="Flat Type", choices=sorted(flat_types), value="4 ROOM")
	flat_model = gr.Dropdown(label="Flat Model", choices=sorted(flat_models), value="Improved")
	floor_area_sqm = gr.Slider(label="Floor Area (sqm)", minimum=30, maximum=200, value=95, step=5)
	storey_level = gr.Slider(label="Storey Level", minimum=1, maximum=50, value=8, step=1)
	flat_age = gr.Slider(label="Flat Age (years)", minimum=0, maximum=99, value=15, step=1)

	predict_btn = gr.Button("🔮 Predict Price", variant="primary")

	with gr.Column():
	predicted_price = gr.Label(label="💰 Predicted Price")
	insights = gr.Markdown(label="📋 Property Summary")

	with gr.Row():
	chart_output = gr.Plot(label="📈 Market Insights")

	# Connect button to function
	predict_btn.click(
	fn=predict_hdb_price,
	inputs=[town, flat_type, flat_model, floor_area_sqm, storey_level, flat_age],
	outputs=[predicted_price, chart_output, insights]
	)

	with gr.Tab("AI Chat Assistant"):
	gr.Markdown("💬 Chat with our AI assistant to get HDB price predictions using natural language!")
	gr.Markdown("Example: 'What would be the price of a 4-room model A flat in Ang Mo Kio with 95 sqm, on the 8th floor, that's 15 years old?'")
	gr.Markdown("You can also say hello, ask how I am, or ask general questions about HDB!")

	chatbot = gr.Chatbot(label="HDB Price Chatbot", height=500)
	msg = gr.Textbox(label="Your question", placeholder="Type your message here...")
	clear = gr.Button("Clear Chat")

	def respond(message, chat_history):
	response, updated_history = chat_with_llm(message, chat_history)
	return updated_history

	msg.submit(respond, [msg, chatbot], [chatbot])
	clear.click(lambda: None, None, [chatbot], queue=False)

	# To run in Colab
	if __name__ == "__main__":
	# Let Gradio automatically find an available port
	demo.launch(server_name="0.0.0.0", share=True)