import os import streamlit as st import json import matplotlib.pyplot as plt import matplotlib.gridspec as gridspec import matplotlib.animation as animation import time from PIL import Image from streamlit_image_comparison import image_comparison import numpy as np #import chromadb from textwrap import dedent import google.generativeai as genai #api_key = os.environ["OPENAI_API_KEY"] #from openai import OpenAI import numpy as np # Assuming chromadb and TruLens are correctly installed and configured #from chromadb.utils.embedding_functions import # Google Langchain from langchain_google_genai import GoogleGenerativeAI #Crew imports from crewai import Agent, Task, Crew, Process # Retrieve API Key from Environment Variable GOOGLE_AI_STUDIO = os.environ.get('GOOGLE_API_KEY') # Ensure the API key is available if not GOOGLE_AI_STUDIO: raise ValueError("API key not found. Please set the GOOGLE_AI_STUDIO2 environment variable.") # Set gemini_llm gemini_llm = GoogleGenerativeAI(model="gemini-pro", google_api_key=GOOGLE_AI_STUDIO) # CrewAI ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ def crewai_process_gemini(research_topic): # Define your agents with roles and goals GeminiAgent = Agent( role='Story Writer', goal='To create a story from bullet points.', backstory="""You are an expert writer that understands how to make the average extraordinary on paper """, verbose=True, allow_delegation=False, llm = gemini_llm, tools=[ GeminiSearchTools.gemini_search ] ) # Create tasks for your agents task1 = Task( description=f"""From {research_topic} create your story by writing at least one sentence about each bullet point and make sure you have a transitional statement between scenes . BE VERBOSE.""", agent=GeminiAgent ) # Instantiate your crew with a sequential process crew = Crew( agents=[GeminiAgent], tasks=[task1], verbose=2, process=Process.sequential ) # Get your crew to work! result = crew.kickoff() return result # Tool import from crewai.tools.gemini_tools import GeminiSearchTools from crewai.tools.mixtral_tools import MixtralSearchTools from crewai.tools.zephyr_tools import ZephyrSearchTools st.set_page_config(layout="wide") # Animation Code +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ # Set up the duration for your animation t0=0 # [hrs] t_end=2 # [hrs] dt=0.005 # [hrs] # Create array for time t=np.arange(t0,t_end+dt,dt) frame_amount=len(t) # Subplot 1 fig2=plt.figure(figsize=(16,9),dpi=120,facecolor=(0.8,0.8,0.8)) gs=gridspec.GridSpec(2,2) ax0=fig2.add_subplot(gs[0,:],facecolor=(0.9,0.9,0.9)) box_object=dict(boxstyle='circle',fc=(0.1,0.9,0.9),ec='r',lw=10) stopwatch0=ax0.text(1400,0.65,'',size=20,color='g',bbox=box_object) def update_plot(num): # 1st subplot stopwatch0.set_text(str(round(t[num],1))+' hrs') return stopwatch0, # HIN Number +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ from SPARQLWrapper import SPARQLWrapper, JSON from streamlit_agraph import agraph, TripleStore, Node, Edge, Config import json # Function to load JSON data def load_data(filename): with open(filename, 'r') as file: data = json.load(file) return data # Dictionary for color codes color_codes = { "residential": "#ADD8E6", "commercial": "#90EE90", "community_facilities": "#FFFF00", "school": "#FFFF00", "healthcare_facility": "#FFFF00", "green_space": "#90EE90", "utility_infrastructure": "#90EE90", "emergency_services": "#FF0000", "cultural_facilities": "#D8BFD8", "recreational_facilities": "#D8BFD8", "innovation_center": "#90EE90", "elderly_care_home": "#FFFF00", "childcare_centers": "#FFFF00", "places_of_worship": "#D8BFD8", "event_spaces": "#D8BFD8", "guest_housing": "#FFA500", "pet_care_facilities": "#FFA500", "public_sanitation_facilities": "#A0A0A0", "environmental_monitoring_stations": "#90EE90", "disaster_preparedness_center": "#A0A0A0", "outdoor_community_spaces": "#90EE90", # Add other types with their corresponding colors } # Function to draw the grid with optional highlighting def draw_grid(data, highlight_coords=None): fig, ax = plt.subplots(figsize=(12, 12)) nrows, ncols = data['size']['rows'], data['size']['columns'] ax.set_xlim(0, ncols) ax.set_ylim(0, nrows) ax.set_xticks(range(ncols+1)) ax.set_yticks(range(nrows+1)) ax.grid(True) # Draw roads with a specified grey color road_color = "#606060" # Light grey; change to "#505050" for dark grey for road in data.get('roads', []): # Check for roads in the data start, end = road['start'], road['end'] # Determine if the road is vertical or horizontal based on start and end coordinates if start[0] == end[0]: # Vertical road for y in range(min(start[1], end[1]), max(start[1], end[1]) + 1): ax.add_patch(plt.Rectangle((start[0], nrows-y-1), 1, 1, color=road['color'])) else: # Horizontal road for x in range(min(start[0], end[0]), max(start[0], end[0]) + 1): ax.add_patch(plt.Rectangle((x, nrows-start[1]-1), 1, 1, color=road['color'])) # Draw buildings for building in data['buildings']: coords = building['coords'] b_type = building['type'] size = building['size'] color = color_codes.get(b_type, '#FFFFFF') # Default color is white if not specified if highlight_coords and (coords[0], coords[1]) == tuple(highlight_coords): highlighted_color = "#FFD700" # Gold for highlighting ax.add_patch(plt.Rectangle((coords[1], nrows-coords[0]-size), size, size, color=highlighted_color, edgecolor='black', linewidth=2)) else: ax.add_patch(plt.Rectangle((coords[1], nrows-coords[0]-size), size, size, color=color, edgecolor='black', linewidth=1)) ax.text(coords[1]+0.5*size, nrows-coords[0]-0.5*size, b_type, ha='center', va='center', fontsize=8, color='black') ax.set_xlabel('Columns') ax.set_ylabel('Rows') ax.set_title('Village Layout with Color Coding') return fig # Title ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ # Tabs +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ # Create the main app with three tabs tab1, tab2, tab3 = st.tabs(["Introduction","Green Village", "Control Room"]) with tab1: st.header("RAGE - A day in the Life of Aya City") # Creating columns for the layout col1, col2 = st.columns([1, 2]) # Displaying the image in the left column with col1: image = Image.open('intro_image.jpg') st.image(image, caption='Green Open Data City Aya') # Displaying the text above on the right with col2: st.markdown(''' On his first day at Quantum Data Institute in Green Open Data City Aya, Elian marveled at the city’s harmonious blend of technology and nature. Guided to his mentor, Dr. Maya Lior, a pioneer in urban data ecosystems, their discussion quickly centered on Aya’s innovative design. Dr. Lior explained data analytics and green technologies were intricately woven into the city's infrastructure, and how they used a Custom GPT called Green Data City to create the design. To interact with the Green Data City design tool click the button below. ''') # Displaying the audio player below the text st.audio('intro_audio.mp3') st.header("Custom GPT Engineering Tools") st.link_button("Create JSON Data for a Green Data Village Population 10,000", "https://chat.openai.com/g/g-4bPJUaHS8-create-a-green-data-village") st.write("Explanation of the Custom GPT") st.write(""" On clicking "Create Data Village" create a Green Data Village following the 4 Steps below. Output a JSON file similar to the Example by complete the four Steps. To generate the provided JSON code, I would instruct a custom GPT to create a detailed description of a hypothetical smart city layout, named "Green Smart Village", with a population of 10,000. This layout should include a grid size of 21x21, a list of buildings and roads, each with specific attributes: Step 1: General Instructions: Generate a smart city layout for "Green Smart Village" with a 21x21 grid. Include a population of 10,000. Step 2: Buildings: For each building, specify its coordinates on the grid, type (e.g., residential, commercial, healthcare facility), size (in terms of the grid), color, and equipped sensors (e.g., smart meters, water flow sensors). Types of buildings should vary and include residential, commercial, community facilities, school, healthcare facility, green space, utility infrastructure, emergency services, cultural facilities, recreational facilities, innovation center, elderly care home, childcare centers, places of worship, event spaces, guest housing, pet care facilities, public sanitation facilities, environmental monitoring stations, disaster preparedness center, outdoor community spaces, typical road, and typical road crossing. Step 3: Assign each building unique sensors based on its type, ensuring a mix of technology like smart meters, occupancy sensors, smart lighting systems, and environmental monitoring sensors. Step 4: Roads: Detail the roads' start and end coordinates, color, and sensors installed. Ensure roads connect significant areas of the city, providing access to all buildings. Equip roads with sensors for traffic flow, smart streetlights, and pollution monitoring. MAKE SURE ALL BUILDINGS HAVE ACCESS TO A ROAD. This test scenario would evaluate the model's ability to creatively assemble a smart city plan with diverse infrastructure and technology implementations, reflecting real-world urban planning challenges and the integration of smart technologies for sustainable and efficient city management. Example: { "city": "City Name", "population": "Population Size", "size": { "rows": "Number of Rows", "columns": "Number of Columns" }, "buildings": [ { "coords": ["X", "Y"], "type": "Building Type", "size": "Building Size", "color": "Building Color", "sensors": ["Sensor Types"] } ], "roads": [ { "start": ["X Start", "Y Start"], "end": ["X End", "Y End"], "color": "Road Color", "sensors": ["Sensor Types"] } ] } """) with tab2: st.header("Green Smart Village Application") # Divide the page into three columns col1, col2, col3 = st.columns(3) with col1: st.header("Today's Agenda") st.write("1. Morning Meeting\n2. Review Project Plans\n3. Lunch Break\n4. Site Visit\n5. Evening Wrap-up") st.header("Agent Advisors") st.write("Would you like to optimize your HIN number?") # Selection box for the function to execute process_selection = st.selectbox( 'Choose the process to run:', ('crewai_process_gemini', 'crewai_process_mixtral_crazy', 'crewai_process_mixtral_normal', 'crewai_process_zephyr_normal', 'crewai_process_phi2') ) # Button to execute the chosen function if st.button('Run Process'): if research_topic: # Ensure there's a topic provided if process_selection == 'crewai_process_gemini': result = crewai_process_gemini(research_topic) elif process_selection == 'crewai_process_mixtral_crazy': result = crewai_process_mixtral_crazy(research_topic) elif process_selection == 'crewai_process_mixtral_normal': result = crewai_process_mixtral_normal(research_topic) elif process_selection == 'crewai_process_zephyr_normal': result = crewai_process_zephyr_normal(research_topic) elif process_selection == 'crewai_process_phi2': result = crewai_process_phi2(research_topic) st.write(result) else: st.warning('Please enter a research topic.') st.header("My Incentive") st.write("Total incentive for HIN optimization") with col2: st.header("Green Smart Village Layout") data = load_data('grid.json') # Ensure this path is correct # Dropdown for selecting a building building_options = [f"{bld['type']} at ({bld['coords'][0]}, {bld['coords'][1]})" for bld in data['buildings']] selected_building = st.selectbox("Select a building to highlight:", options=building_options) selected_index = building_options.index(selected_building) selected_building_coords = data['buildings'][selected_index]['coords'] # Draw the grid with the selected building highlighted fig = draw_grid(data, highlight_coords=selected_building_coords) st.pyplot(fig) # Assuming sensors are defined in your data, display them sensors = data['buildings'][selected_index].get('sensors', []) st.write(f"Sensors in selected building: {', '.join(sensors)}") with col3: st.header("Check Your HIN Number") # config = Config(height=400, width=400, nodeHighlightBehavior=True, highlightColor="#F7A7A6", directed=True, collapsible=True) if sensors: # Check if there are sensors to display graph_store = TripleStore() building_name = f"{data['buildings'][selected_index]['type']} ({selected_building_coords[0]}, {selected_building_coords[1]})" # Iterate through each sensor and create a triple linking it to the building for sensor in sensors: sensor_id = f"Sensor: {sensor}" # Label for sensor nodes # Correctly add the triple without named arguments graph_store.add_triple(building_name, "has_sensor", sensor_id) # Configuration for the graph visualization agraph_config = Config(height=300, width=300, nodeHighlightBehavior=True, highlightColor="#F7A7A6", directed=True, collapsible=True) # Display the graph agraph(nodes=graph_store.getNodes(), edges=graph_store.getEdges(), config=agraph_config) hin_number = st.text_input("Enter your HIN number:") if hin_number: st.write("HIN number details...") # Placeholder for actual HIN number check with tab3: st.header("Control Room") st.write("Synthetic data should be used to drive control room") """ Smart meters Water flow sensors Temperature and humidity sensors Occupancy sensors HVAC control systems Smart lighting Security cameras Indoor air quality sensors Smart lighting systems Energy consumption monitors Patient monitoring systems Environmental monitoring sensors Energy management systems Soil moisture sensors Smart irrigation systems Leak detection sensors Grid monitoring sensors GPS tracking for vehicles Smart building sensors Dispatch management systems High-speed internet connectivity Energy consumption monitoring Smart security systems Environmental control systems Security systems Smart HVAC systems Smart locks Water usage monitoring Smart inventory management systems Waste level sensors Fleet management systems for sanitation vehicles Air quality sensors Weather stations Pollution monitors Early warning systems Communication networks Adaptive lighting systems Traffic flow sensors Smart streetlights """ """ Animation Code ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ fig2=plt.figure(figsize=(16,9),dpi=120,facecolor=(0.8,0.8,0.8)) gs=gridspec.GridSpec(2,2) stopwatch_ani=animation.FuncAnimation(fig2,update_plot,frames=frame_amount,interval=20,repeat=True,blit=True) st.pyplot(fig2) """