Fetch_v3.8.py

#Python3

#This program creates geofence data based on user input and plotting locations provided in CSV, TSV, and Excel formats

#   TO DO - Time slider is not updated when picking dates w calendar, declutter
#           Support parsing KML as input
#           Add time filter support to cell site maps
#           Add details to cell site sector wedges

# Completed Updates:
# 1.  Added error handling for time values in filtering, declutter, and GPX support
# 2.  Added support for KML Tours
# 3.  Updated support for vapor trails
# 4.  Improved KML creation UI
# 5.  Geocoder improvements


import simplekml #the library used to map longitudes and latitudes on google earth
import pandas #used to read spreadsheet data
import re
import operator
import streamlit as st
import chardet      #   used to check file encodings
import os
from polycircles import polycircles     #   creates kml polygons
import leafmap.foliumap as leafmap      #   maps 
from leafmap.foliumap import plugins    #   maps
import geopandas                        
import folium                           #   maps
from math import asin, atan2, cos, degrees, radians, sin    #   calculates shapes and polygons on sphere
from folium.plugins import Draw, Geocoder, TimestampedGeoJson       
from streamlit_folium import st_folium          #   used to create geofences
import datetime
import geocoder                         #   search bar for geofence, api calls for address and ip lookups
import gpxpy
import numpy as np
from dateutil import parser
import time


now = datetime.datetime.now()
st.set_page_config(
   page_title="Fetch v3.8",
   #page_icon="🔴",
   layout="wide",
   initial_sidebar_state="expanded",
    menu_items={}
)
logo = ("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")
header_html = "<img src='data:image/png;base64,{}' class='img-fluid'>".format(logo)
st.markdown(
    header_html, unsafe_allow_html=True,
)
#Custom button color to bring prominence to executable actions

m = st.markdown("""
        <style>
        div.stButton > button:first-child {
            background-color: #ff0000;
            color:#ffffff;
        }
        div.stButton > button:hover {
            background-color: #8b0000;
            color:#ff0000;
            }
        </style>""", unsafe_allow_html=True)
#This removes Streamlit default settings icons
hide_streamlit_style = """
            <style>
            #MainMenu {visibility: visible;}
            footer {visibility: hidden;}
            </style>
            """
st.markdown(hide_streamlit_style, unsafe_allow_html=True) 

### Global Variables ###
get_headings = ""
selected_encoding = ""
icon_options = ["Yellow Paddle", "Green Paddle", "Blue Paddle", "White Paddle", "Teal Paddle", "Red Paddle", "Yellow Pushpin", "White Pushpin", "Red Pushpin", "Square"]
selected_icon = {'Square' :'http://maps.google.com/mapfiles/kml/shapes/placemark_square.png','Yellow Pushpin' : "http://maps.google.com/mapfiles/kml/pushpin/ylw-pushpin.png",'Red Pushpin' : "http://maps.google.com/mapfiles/kml/pushpin/red-pushpin.png",'White Pushpin' : "http://maps.google.com/mapfiles/kml/pushpin/wht-pushpin.png",'Red Paddle' : "http://maps.google.com/mapfiles/kml/paddle/red-circle.png",'Green Paddle' : "http://maps.google.com/mapfiles/kml/paddle/grn-circle.png",'Blue Paddle' : "http://maps.google.com/mapfiles/kml/paddle/blu-circle.png",'Teal Paddle' : "http://maps.google.com/mapfiles/kml/paddle/ltblu-circle.png",'Yellow Paddle' : "http://maps.google.com/mapfiles/kml/paddle/ylw-circle.png",'White Paddle' : "http://maps.google.com/mapfiles/kml/paddle/wht-circle.png"}
invalid_ips = ['0', '10.', '127.0.0.1','172.16', '172.17', '172.18', '172.19', '172.2',  '172.21', '172.22', '172.23', '172.24', '172.25',
            '172.26', '172.27', '172.28', '172.29', '172.30',  '172.31', '192.168', '169.254', "255.255" ,"fc00"]
geo_list = []

####    Functions Live Here     ######
def convert_to_datetime_and_string(timestamp_string):  # function takes a timestamp string and converts to datetime and a uniform string output
    # parses the timestamp string into a datetime object
    datetime_value = parser.parse(timestamp_string)

    # Formats the datetime object into the desired string format
    formatted_string = datetime_value.strftime("%Y-%m-%dT%H:%M:%S")

    return datetime_value, formatted_string

def get_point_at_distance(lat1, lon1, d, bearing, R=6371):  # used to draw tower wedges
    """
    lat: initial latitude, in degrees
    lon: initial longitude, in degrees
    d: target distance from initial
    bearing: (true) heading in degrees
    R: optional radius of sphere, defaults to mean radius of earth

    Returns new lat/lon coordinate {d}km from initial, in degrees
    """
    lat1 = radians(lat1)
    lon1 = radians(lon1)
    a = radians(bearing)
    lat2 = asin(sin(lat1) * cos(d/R) + cos(lat1) * sin(d/R) * cos(a))
    lon2 = lon1 + atan2(
        sin(a) * sin(d/R) * cos(lat1),
        cos(d/R) - sin(lat1) * sin(lat2)
    )
    return (degrees(lat2), degrees(lon2),)

def make_geofence_map():

    help_Box = st.expander(label="Help")
    with st.form("geoform"):
        user_geo_input = st.text_input("Street and I.P. Address Search",placeholder=None,)
        search_geo_button = st.form_submit_button("Search")
    with help_Box:
        st.write("""Use the shape elements in the map toolbar to create shapes for the geofence. \n\nOnce your geofence has been drawn, 
        the coordinates will populate below the map.  \n\nYou can add the coordinates to your clipboard to be pasted elsewhere or you 
        can save the entire page using your browser.\n\nATTENTION: Internet Protocol searches ARE NOT INDICATIVE OF THE LOCATION WHERE THE IP WAS USED. 
        THEY INDICATE A GENERAL AREA ASSOCIATED WITH THE SERVICE PROVIDER AND MAY BE COMPLETELY INACCURATE IN SOME INSTANCES. \n\nVerify 
        any addresses or locations presented by the search bar. \n\nAccuracy varies based on location.""")
    global geomap
    geomap = folium.Map(zoom_start=14)
    geomap.fit_bounds([[27,-140],[48,-59]])
    Draw(export=True,draw_options=({'circle': False,'circlemarker':False, 'marker':False})).add_to(geomap)
    folium.TileLayer(tiles = 'https://server.arcgisonline.com/ArcGIS/rest/services/World_Imagery/MapServer/tile/{z}/{y}/{x}',
    attr = 'Esri',
    name = 'Esri Satellite',
    overlay = False,
    control = True
    ).add_to(geomap)
    folium.LayerControl(position="topright", collapsed=True).add_to(geomap)
            
    if len(user_geo_input) == 0:
        global search_latlng
        search_latlng = [40,-100]

    if len(user_geo_input) > 0:
        ipv4_ipv6_regex = "(^\s*((([0-9]|[1-9][0-9]|1[0-9]{2}|2[0-4][0-9]|25[0-5])\.){3}([0-9]|[1-9][0-9]|1[0-9]{2}|2[0-4][0-9]|25[0-5]))\s*$)|(^\s*((([0-9A-Fa-f]{1,4}:){7}([0-9A-Fa-f]{1,4}|:))|(([0-9A-Fa-f]{1,4}:){6}(:[0-9A-Fa-f]{1,4}|((25[0-5]|2[0-4]\d|1\d\d|[1-9]?\d)(\.(25[0-5]|2[0-4]\d|1\d\d|[1-9]?\d)){3})|:))|(([0-9A-Fa-f]{1,4}:){5}(((:[0-9A-Fa-f]{1,4}){1,2})|:((25[0-5]|2[0-4]\d|1\d\d|[1-9]?\d)(\.(25[0-5]|2[0-4]\d|1\d\d|[1-9]?\d)){3})|:))|(([0-9A-Fa-f]{1,4}:){4}(((:[0-9A-Fa-f]{1,4}){1,3})|((:[0-9A-Fa-f]{1,4})?:((25[0-5]|2[0-4]\d|1\d\d|[1-9]?\d)(\.(25[0-5]|2[0-4]\d|1\d\d|[1-9]?\d)){3}))|:))|(([0-9A-Fa-f]{1,4}:){3}(((:[0-9A-Fa-f]{1,4}){1,4})|((:[0-9A-Fa-f]{1,4}){0,2}:((25[0-5]|2[0-4]\d|1\d\d|[1-9]?\d)(\.(25[0-5]|2[0-4]\d|1\d\d|[1-9]?\d)){3}))|:))|(([0-9A-Fa-f]{1,4}:){2}(((:[0-9A-Fa-f]{1,4}){1,5})|((:[0-9A-Fa-f]{1,4}){0,3}:((25[0-5]|2[0-4]\d|1\d\d|[1-9]?\d)(\.(25[0-5]|2[0-4]\d|1\d\d|[1-9]?\d)){3}))|:))|(([0-9A-Fa-f]{1,4}:){1}(((:[0-9A-Fa-f]{1,4}){1,6})|((:[0-9A-Fa-f]{1,4}){0,4}:((25[0-5]|2[0-4]\d|1\d\d|[1-9]?\d)(\.(25[0-5]|2[0-4]\d|1\d\d|[1-9]?\d)){3}))|:))|(:(((:[0-9A-Fa-f]{1,4}){1,7})|((:[0-9A-Fa-f]{1,4}){0,5}:((25[0-5]|2[0-4]\d|1\d\d|[1-9]?\d)(\.(25[0-5]|2[0-4]\d|1\d\d|[1-9]?\d)){3}))|:)))(%.+)?\s*$)"
        
        
        if bool(re.search(ipv4_ipv6_regex, user_geo_input)) == False:   #    searches user input for alphabet if true geocode address search - false ip address search
            try:
                # search_geo_results = geocoder.osm(user_geo_input) # Limits are too restrictive for free use
                search_geo_results = geocoder.arcgis(user_geo_input)
                search_latlng = search_geo_results.latlng
                search_info_return = search_geo_results.json['address']
                zoom = 17
                # print(search_info_return)
            except TypeError:
                st.error("Search input produced no results")
            
        if bool(re.search(ipv4_ipv6_regex, user_geo_input)) == True:   #    searches user input for alphabet if true geocode address search - false ip address search
            search_geo_results = geocoder.ipinfo(user_geo_input)
            search_latlng = search_geo_results.latlng
            search_info_return = search_geo_results.json
            dont_show = "raw"
            ip_stats = [value for key, value in search_info_return.items() if key not in dont_show]
            zoom = 11
            st.markdown(":blue[I.P. geolocation is a rough estimate related to provider coverage, and the point provided does not indicate use/user location.]")
            st.json(search_info_return, expanded=False)
            print(search_info_return)
            
        
        try:        
            geomap = folium.Map(location=search_latlng,zoom_start=zoom)  
            folium.Marker(location=search_latlng,draggable=True,).add_to(geomap)
            Draw(export=True,draw_options=({'circle': False,'circlemarker':False, 'marker':False})).add_to(geomap)
            folium.TileLayer(tiles = 'https://server.arcgisonline.com/ArcGIS/rest/services/World_Imagery/MapServer/tile/{z}/{y}/{x}',
            attr = 'Esri',
            name = 'Esri Satellite',
            overlay = False,
            control = True
            ).add_to(geomap)
            folium.LayerControl(position="topright", collapsed=True).add_to(geomap)
        except UnboundLocalError:
            print("geomap issue line 159")
    # else:
    #     geomap = folium.Map(location=search_latlng,zoom_start=3) 
    
    outputmap = st_folium(geomap, width=1500, height=900)
    
    try:        #   pulls the lats and longs from the returned JSON encoded map points
        parse1 = (outputmap['last_active_drawing'])
        parse2 = (parse1['geometry'])
        parse3 = (parse2['coordinates'])
        st.subheader("Geofence Coordinates")
        text_of_coords = "Latitude, Longitude\n"
        for list in parse3:
            for coord in list:
                lon, lat = coord[0], coord[1]
                text_of_coords = text_of_coords + "\n" + (str(lat) + ", " + str(lon)) + "\n"
        texting = st.write(text_of_coords)
        download_coords = st.download_button(label="Download Coordinates", data=text_of_coords, file_name="Fetch_GeoFence_Coordinates.txt")
        
    except TypeError:
        # print("no data to populate - add some data")
        pass



def parse_text_for_IPs(text):  #used to map ips
    ipv4_pattern = r'(?:\d{1,3}\.){3}\d{1,3}\b'
    ipv6_pattern = r'(([0-9a-fA-F]{1,4}:){7,7}[0-9a-fA-F]{1,4}|([0-9a-fA-F]{1,4}:){1,3}(:[0-9a-fA-F]{1,4}){1,4}|([0-9a-fA-F]{1,4}:){1,2}(:[0-9a-fA-F]{1,4}){1,5}|[0-9a-fA-F]{1,4}:((:[0-9a-fA-F]{1,4}){1,6})|:((:[0-9a-fA-F]{1,4}){1,7}|:)|fe80:(:[0-9a-fA-F]{0,4}){0,4}%[0-9a-zA-Z]{1,}|::(ffff(:0{1,4}){0,1}:){0,1}((25[0-5]|(2[0-4]|1{0,1}[0-9]){0,1}[0-9])\.){3,3}(25[0-5]|(2[0-4]|1{0,1}[0-9]){0,1}[0-9])|([0-9a-fA-F]{1,4}:){1,4}:((25[0-5]|(2[0-4]|1{0,1}[0-9]){0,1}[0-9])\.){3,3}(25[0-5]|(2[0-4]|1{0,1}[0-9]){0,1}[0-9]))'

    ipv4_addresses = re.findall(ipv4_pattern, text)
    ipv6_addresses = re.findall(ipv6_pattern, text)
    
    ipv6_list = []
    ip_list = list(set(ipv4_addresses))

    for address in ipv6_addresses:
        clean_ipv6 = [item for item in address if len(item) > 16]
        if clean_ipv6:      # checks for empty lists
            ipv6_list.append(clean_ipv6)
    unique_ip6_list = [str(inner_list[0]) for inner_list in ipv6_list]
    unique_ip6_list = list(set(unique_ip6_list))
    ip_list.extend(unique_ip6_list)
    return ip_list

def get_IP_locale(invalidList, IPs):    #used to map ips
    valid_only = [address for address in IPs if not any(address.startswith(inval) for inval in invalidList)] # removes invalid ips from list of bad ips
    for thing in valid_only:
        pull_geo_data = geocoder.ipinfo(thing)
        # Check if both 'error' and '429' are present in the response
        if "error" in pull_geo_data.json and pull_geo_data.json.get("error") == "429":
            st.warning("Too many requests for IP lookups have occurred on Fetch today. Please try again later.")
            break
        else:
            geo_list.append(pull_geo_data.json)     # Saves data to list in global variable geo_list
def geo_ip_to_Dataframe(geo_list):  #used to map ips
    df = pandas.json_normalize(geo_list)
    df = df.dropna(how='all') #removes entirely empty rows
    columns = df.columns
    columnnamelist = []
    for name in columns:
        columnnamelist.append(name.upper())
    df.columns = columnnamelist
    df.rename(columns={"IP": 'IP ADDRESS','LAT': 'LATITUDE', 'LNG': "LONGITUDE", 'ORG': "SERVICE PROVIDER"}, inplace=True)
    return (df)

def convert_df(df):
    return df.to_csv().encode('utf-8')
def make_IPaddress_Map():   #used to map ips
    # help_Box = st.expander(label="Help")
    user_location = st.text_input("Place Name or Address - Use to Add a Relevant Location to the Map (Place e-mail received, point of comparison, etc)")
    ipdata = st.text_area("Input Data with IP Addresses or an E-Mail Header",height=200)
    ip_geo_button = st.button("Search")
    

    if ip_geo_button == True:
        
        search_geo_results = geocoder.arcgis(user_location)
        search_latlng = search_geo_results.json
        # print(search_latlng)
        
        try:
            parsed_IPs = parse_text_for_IPs(ipdata) # Parses text for IP addresses
            get_IP_locale(invalid_ips, parsed_IPs)  # Filters out local ip and keeps valid public ips
            datfram = geo_ip_to_Dataframe(geo_list=geo_list)  
            if datfram.empty:
                st.warning("Warning: No values resembling public IP addresses were found. Check the submitted data.")
              
            show_these = ('IP ADDRESS', 'STATUS','SERVICE PROVIDER', 'CITY', 'STATE', 'COUNTRY','LATITUDE', 'LONGITUDE')
            # show_these = None
            st.dataframe(data=datfram,hide_index=True,column_order=show_these) 
            csv = convert_df(datfram)
            st.download_button(label="Download as CSV",
                            data=csv,
                            file_name='Fetch_IP_Lookup.csv',
                            mime='text/csv',
                            )   
        
            cleandf = pandas.DataFrame.dropna(datfram, subset=["LONGITUDE","LATITUDE"])
            cleandf = cleandf.reset_index()
          
            
            gdf = geopandas.GeoDataFrame(cleandf, geometry=geopandas.points_from_xy(cleandf.LONGITUDE, cleandf.LATITUDE))
        except KeyError:
            print("key error in makeipaddressmap")
            pass
        
        try:
            user_gdf = pandas.json_normalize(search_latlng)
        except NotImplementedError:
            # st.info("No Place Name or Address provided. Attempting to Map IPs.")
            pass
        try:
            user_gdf = geopandas.GeoDataFrame(user_gdf, geometry=geopandas.points_from_xy(user_gdf.lng, user_gdf.lat))
        except UnboundLocalError:
            pass
        ipmap = leafmap.Map(zoom=2)    
        ipmap.add_basemap(basemap='ROADMAP')
        ipmap.add_basemap(basemap='TERRAIN')
        ipmap.add_basemap(basemap='HYBRID')
        ipmap.add_basemap(basemap="CartoDB.DarkMatter") 
        # ipmap.zoom_to_gdf(gdf) 
        try:
            user_spot = ipmap.add_circle_markers_from_xy(data=user_gdf, x="lng", y="lat",color='Red',fill_color="White")
        except UnboundLocalError:
            pass
        try:
            circle_Points = ipmap.add_circle_markers_from_xy(data=gdf, x="LONGITUDE", y="LATITUDE",color="Yellow",fill_color="Yellow", radius=5)
            ipmap.to_streamlit()
            downloadfile = ipmap.to_html()               # for downloads
            download_test = st.download_button(label="Download HTML Map", data=downloadfile,file_name="Fetch_Analysis_Map.html")
        except UnboundLocalError:
            pass
        #     st.error("Input Data is required OR No location data was located from the provided data.")


def make_map(in_df):       #bring in pandas dataframe
    try:
        gdf = geopandas.GeoDataFrame(in_df, geometry=geopandas.points_from_xy(in_df.LONGITUDE, in_df.LATITUDE))
        map_Type = st.radio("Select Map Type", options=["Clustered Markers", "Points & Trails", "Heat Map", "Cell Sites"], horizontal=True)
        Map = leafmap.Map()
        #Zooms to bounds of the dataframe
        Map.zoom_to_gdf(gdf) 
        Map.add_basemap(basemap='ROADMAP')
        # Map.add_basemap(basemap='SATELLITE')
        Map.add_basemap(basemap='TERRAIN')
        Map.add_basemap(basemap='HYBRID')
        Map.add_basemap(basemap="CartoDB.DarkMatter") 
        

        if map_Type == "Clustered Markers":
            grouped_Points = Map.add_points_from_xy(gdf, x="LONGITUDE", y="LATITUDE", min_width=10,max_width=250,layer_name="Clustered Points", add_legend=False)
        
        if map_Type == "Heat Map":
            in_df.columns = in_df.columns.str.upper()
            weight_type = st.radio("Select Weight Type", options=["Point Density", "Weighted Density"], horizontal=True)
            if weight_type == "Point Density":
                set_weight_to_one = gdf.assign(weight_column=1)
                # print(set_weight_to_one)
                try:
                    heatmap = Map.add_heatmap(set_weight_to_one, longitude="LONGITUDE", latitude="LATITUDE",value='weight_column',name="Heat Map", radius=25,)
                except Exception:
                    st.info("Heat Maps use weighted numeric values to accomodate issues like population density. Select column for your dataset.")

            if weight_type == "Weighted Density":
                weighted_value_column = st.selectbox("Weighted Value Column", options=gdf.columns)
                try:
                    heatmap = Map.add_heatmap(gdf, longitude="LONGITUDE", latitude="LATITUDE",value=weighted_value_column,name="Heat Map", radius=25,)
                except Exception:
                    st.info("Heat Maps use weighted numeric values to accomodate issues like population density. Select column for your dataset.")


        if map_Type == "Points & Trails":
            st.markdown("---")
            Map.zoom_to_gdf(gdf) 
            points_or_path = st.radio(label="Select map activity", options=["Markers", "Show Point Progression", "Vapour Trail"], horizontal=True)
            
            if points_or_path == "Markers":     #Shows markers only
                color = st.selectbox(label="Choose",options=['DarkRed', 'Yellow','Pink', 'Green', 'Teal', "Blue", "White"])
                circle_Points = Map.add_circle_markers_from_xy(data=gdf, x="LONGITUDE", y="LATITUDE",color=color,fill_color=color, radius=5)

            if points_or_path == "Show Point Progression":      #Shows the moving path between markers
                list_of_path_points = []    #stores coordinates from dataframe, but in long/lat format
                pathpointforreal = []       #stores corrected coordinates in lat/long form to be used by the Antpath tool
                color = st.selectbox(label="Choose",options=['DarkRed', 'Yellow','Pink', 'Green', 'Teal', "Blue", "White"])
                
                try:
                    circle_Points = Map.add_circle_markers_from_xy(data=gdf, x="LONGITUDE", y="LATITUDE",color=color,fill_color=color, radius=5)
                except ValueError:
                    st.error("Select")
                for index, row in gdf.iterrows():
                    for pt in list(row['geometry'].coords):
                        list_of_path_points.append(pt)
                
                for ting in list_of_path_points:        #   Takes list and swaps from long/lat tuple and strings to list lat/long floats
                    [longy, laty] = ting
                    ltlng = (str(laty) + "," + str(longy))
                    ltlng2list = [float(value) for value in ltlng.split(",")]
                    # print(ltlng2list)
                    pathpointforreal.append(ltlng2list)
                plugins.AntPath(locations=pathpointforreal,color=color).add_to(Map)

            #   GOTTA ORDER THE DATAFRAME BY TIME AND DATE THEN ADD THE POINTS IN ORDER TO A LIST TO BE READ BY THE ANTPATH

            if points_or_path == "Vapour Trail":
                choose_datetime_column = st.selectbox("Date / Time Column", options=gdf.columns)
                time_interval = st.radio("Time Interval to Display", options=['Daily', 'Hourly', '10 Minutes', '1 Minute'],horizontal=True)
                if time_interval == 'Daily':
                    chosen_interval = 'PT24H'
                if time_interval == 'Hourly':
                    chosen_interval = 'PT1H'
                if time_interval == '10 Minutes':
                    chosen_interval = 'PT10M'  
                if time_interval == '1 Minute':
                    chosen_interval = 'PT1M'   
                # Create a FeatureGroup for the vapor trail
                vapor_trail = folium.FeatureGroup(name='Vapor Trail')
                vapor_trail.add_to(Map)

                travel_history = []
                # Iterate through the DataFrame
                for i in range(len(gdf) - 1):
                    row1 = gdf.iloc[i]
                    row2 = gdf.iloc[i + 1]
                    if 'datetime.datetime' in str(type(row1[choose_datetime_column])):
                        row1_timestampstr = (row1[choose_datetime_column]).strftime("%Y-%m-%dT%H:%M:%S")
                        row2_timestampstr = (row2[choose_datetime_column]).strftime("%Y-%m-%dT%H:%M:%S")
                    else:
                        row1_timestampstr = (row1[choose_datetime_column])
                        row2_timestampstr = (row2[choose_datetime_column])
                                
                    # Extract coordinates and datetime from two consecutive rows
                    coord = [[row1["LONGITUDE"], row1["LATITUDE"]],[row2["LONGITUDE"], row2["LATITUDE"]]]
                    # time = [row1[choose_datetime_column], row2[choose_datetime_column]]
                    time = [row1_timestampstr, row2_timestampstr]
                    # Create a dictionary entry and add it to the list
                    entry = {"coord": coord, "time": time}
                    # print(entry)
                    travel_history.append(entry)
                # Switch the order of coordinates to (longitude, latitude) and create a GeoJSON feature collection
                feature_collection = {
                    "type": "FeatureCollection",
                    "features": [
                        {
                        "type": "Feature",
                            "geometry": {
                            "type": "LineString",
                                "coordinates": entry["coord"]#[::-1],  # Switch the order here
                                
                            },
                            "properties": {
                            "times": entry["time"],
                            "style": {
                                    "color": "blue",
                                    "weight": 3,
                            },
                            },
                        }
                        for entry in travel_history
                    ]
                }

                # # Convert datetime strings to datetime objects for TimestampedGeoJson
                # for entry in travel_history:
                #     entry["time"] = [datetime.datetime.strptime(t, '%Y-%m-%d %H:%M:%S.%f') for t in entry["time"]]

                # Create a TimestampedGeoJson layer for the vapor trail
                vapor_trail_layer = TimestampedGeoJson(
                    feature_collection,
                    period=chosen_interval,  # Interval for animation (adjust as needed) set an option in gui
                    auto_play=True,  # Automatically play the animation
                    loop=True,  # Loop the animation
                    date_options="YYYY-MM-DD HH:mm:ss",  # Date format for timestamps
                    add_last_point=False,  # Show the last point
                    # duration="P1D",  # Duration for each point (adjust as needed)
                )

                # Add the vapor trail layer directly to the map
                vapor_trail_layer.add_to(Map)
            

                # Add LayerControl to switch the vapor trail on and off
                folium.LayerControl().add_to(Map)
        
        if map_Type == "Cell Sites":
            towermastpoint = Map.add_circle_markers_from_xy(data=gdf, x="LONGITUDE", y="LATITUDE",color='white',fill_color='white', radius=1)

            gdf.columns = gdf.columns.str.upper()
            gdf.geometry = gdf["GEOMETRY"]
            Map.zoom_to_gdf(gdf) 
            
            st.markdown("---")

            wedge_color = st.selectbox("Sector Color", options=['Red', 'Blue', 'Green', 'Purple', 'Orange', 'DarkRed', 'Beige', 'DarkBlue', 'DarkGreen', 'CadetBlue', 'Pink', 'LightBlue', 'LightGreen', 'Gray', 'Black', 'LightGray'])
        
            radii_list = ["1.5 Miles", "1 Kilometer"]
            for oto in in_df.columns:
                radii_list.append(oto)
            radii = st.selectbox("Sector Footprint Size", options=radii_list)
            if radii == "1.5 Miles":
                in_df["1.5 Miles"] = pandas.Series(2414 for x in range(len(in_df.index)))
            if radii == "1 Kilometer":
                in_df["1 Kilometer"] = pandas.Series(1000 for x in range(len(in_df.index)))
            Azimuth = st.selectbox("Sector Azimuth", options=in_df.columns)   
            beam_width = st.selectbox("Sector Beam Width", options=in_df.columns, placeholder='None')
            try:
                for index, row in gdf.iterrows():           #   iterates through the data frame to place points,shapes
                
                    # plugins.SemiCircle((row["LATITUDE"],row["LONGITUDE"]),      #wedge shape 
                    # radius=row[radii]/2,
                    # direction=row[Azimuth],
                    # arc=row[beam_width],
                    # color=None,
                    # fill_color=wedge_color,
                    # opacity=1,
                    # fill_opacity=.5,
                    # popup=('<br>'.join(f'{k}: {v}' for k, v in row.items()))).add_to(Map)

                
                    length = row[radii]/1000  #convert to meters
                    # print(length/1000)
                    half_beamwidth = int(row[beam_width]) / 2
                    upside =  (row[Azimuth] + half_beamwidth)  #calc angle from center of beam up
                    upside %= 360       # accomodates crossing 360 degree point
                    downside = (row[Azimuth] - half_beamwidth)  #calc angle from center of beam down
                    downside %= 360      # accomodates crossing 360 degree point
                    # print("AZ- "+str(row[Azimuth]) + " up-" + str(upside) + " down-" + str(downside))
                
                    up_lat, up_lon = get_point_at_distance(row["LATITUDE"], row["LONGITUDE"],d=length,bearing=upside)
                    dwn_lat, dwn_lon = get_point_at_distance(row["LATITUDE"], row["LONGITUDE"],d=length,bearing=downside)
                    leafmap.folium.PolyLine([[row["LATITUDE"],row["LONGITUDE"]], [up_lat,up_lon]],color=wedge_color).add_to(Map)    # lines for exterior wedge shape
                    leafmap.folium.PolyLine([[row["LATITUDE"],row["LONGITUDE"]], [dwn_lat,dwn_lon]],color=wedge_color).add_to(Map)
                    plugins.SemiCircle((row["LATITUDE"],row["LONGITUDE"]),      #wedge shape 
                    radius=row[radii]/2,
                    direction=row[Azimuth],
                    arc=row[beam_width],
                    color=None,
                    fill_color=wedge_color,
                    opacity=1,
                    fill_opacity=.5,
                    popup=('<br>'.join(f'{k}: {v}' for k, v in row.items()))).add_to(Map)
            except TypeError:
                st.info("Assign columns for Sector Footprint Size (Radius from Station in Meters), Tower Direction/Azimuth (Degrees), & Beam Width (Degrees)")
                pass
            except ValueError:
                st.info("Assign columns for Sector Footprint Size (Radius from Station in Meters), Tower Direction/Azimuth (Degrees), & Beam Width (Degrees)")
                pass
    
        
        Map.to_streamlit()
        
        col1, col2, col3, col4, col5 = st.columns(5)
        with col1:
            # sav_HTML = st.button("Export to HTML")  # for use with local save of HTML
            downloadfile = Map.to_html()               # for downloads
            download_test = st.download_button(label="Download HTML Map", data=downloadfile,file_name="Fetch_Analysis_Map.html")
        with col2:
            print("")
        with col3:
            print("")
        with col4:
            print("")
        with col5:
            print("")
    except AttributeError:
        st.error("No Latitude and Longitude columns found in the data provided.")
    except ValueError:
        st.error("Invalid symbols were found in Lat/Long data columns. Please remove any non-numeric characters.")
        
def get_footprint_color(icon_Color):
    if "Yellow" in icon_Color:
        footprint_color = simplekml.Color.changealphaint(50, simplekml.Color.yellow)
    if "Red" in icon_Color:
        footprint_color = simplekml.Color.changealphaint(100, simplekml.Color.red)
    if "Blue" in icon_Color:
        footprint_color = simplekml.Color.changealphaint(100, simplekml.Color.blue)
    if "White" in icon_Color:
        footprint_color = simplekml.Color.changealphaint(100, simplekml.Color.white)
    if "Green" in icon_Color:
        footprint_color = simplekml.Color.changealphaint(100, simplekml.Color.green)
    if "Teal" in icon_Color:
        footprint_color = simplekml.Color.changealphaint(100, simplekml.Color.lightblue)
    if "Square" in icon_Color:
        footprint_color = simplekml.Color.changealphaint(200, simplekml.Color.white)
    return footprint_color

def HTML_output_file(name_for_file):
    try:
        name_for_file = name_for_file + ".html"
    except Exception:
        st.error("Provide map name above")
    out_folder = os.path.expanduser('~\\Documents\\Fetch_Maps\\')
    if os.path.exists(out_folder) == False:
        os.makedirs(out_folder)
    else:
        pass
    out_file = os.path.expanduser(out_folder+name_for_file)
    return out_file

def KML_output_file(name_for_file):
    name_for_file = name_for_file + ".kml"
    out_folder = os.path.expanduser('~\\Documents\\Fetch_Maps\\')
    if os.path.exists(out_folder) == False:
        os.makedirs(out_folder)
    else:
        pass
    out_file = os.path.expanduser(out_folder+name_for_file)
    return out_file

def get_file_encoding(infile):      #checks file encoding
    return (chardet.detect(infile.read()))
 
def make_dataframe(infile, outfile):       #   changes input file to pandas dataframe
    if (".xls") in str(infile):     #   This will work for xls and xlsx file formats
        dataf = pandas.read_excel(infile)
    elif (".csv") in str(infile) or (".txt") in str(infile):
        try:
            dataf = pandas.read_csv(infile, encoding=selected_encoding)
        except UnicodeError:
            st.error("Decoding error. Try another encoding method.")
            pass 
    elif (".tsv") in str(infile):
        try:
            dataf = pandas.read_csv(infile, encoding=selected_encoding, sep=("\t"))
        except UnicodeError:
            st.error("Decoding error. Try another encoding method.")
            pass

    elif (".gpx") in str(infile):
        # with open(infile, 'r') as f:
        gpx = gpxpy.parse(infile)
        # Convert to a dataframe one point at a time.
        points_data = []
        # Loop through all points in all track segments
        for track in gpx.tracks:
            for segment in track.segments:
                for point in segment.points:
                    # Create a dictionary to store the latitude, longitude, elevation, and time values for the point
                    point_data = {
                        'latitude': point.latitude,
                        'longitude': point.longitude,
                        'elevation': point.elevation,
                        'time': point.time
                    }
                    # Append the dictionary to the list
                    points_data.append(point_data)
        dataf = pandas.DataFrame.from_records(points_data)


    n = lines_t0_remove
    if n > 0:
        dataf.columns = dataf.iloc[n-1] 
    try:  
        dataf.columns = dataf.columns.str.upper()
        dataf = dataf[0:]
        dataf = dataf.iloc[n:]
        first_five_lines = dataf.head(6)
        first_five_lines = first_five_lines.loc[:,~first_five_lines.columns.duplicated()]
        st.dataframe(data=first_five_lines, use_container_width=True)
        headers = dataf.columns.to_list()
        try:
            dataf['LATITUDE'].replace('', np.nan, inplace=True)     # added to address NaN values in dataframe
            dataf.dropna(subset=['LATITUDE'], inplace=True)
        except KeyError:
            st.error("No 'LATITUDE' column found in data set.")
        try:
            dataf['LONGITUDE'].replace('', np.nan, inplace=True)
            dataf.dropna(subset=['LONGITUDE'], inplace=True)
        except KeyError:
            st.error("No 'LONGITUDE' column found in data set.")
        return headers, dataf 
    except AttributeError:
        st.error('Ensure that the data set is formatted correctly and includes a "Latitude" and "Longitude" column.')                


def create_kml_tour(df, output_file, altitude, tilt, linger, time_column, icon, footprint, radii):
    """
    Creates a KML file with a Google Earth tour from a DataFrame.

    Parameters:
    df (DataFrame): A DataFrame with 'longitude', 'latitude', and 'time' columns.
    output_file (str): Path to the output KML file.
    altitude (int): Camera height in meters.
    tilt (int): Camera tilt.
    linger (float): Seconds to rest on each point.
    time_column (str): Column name for time data.
    icon (str): Icon style for map points.
    footprint (bool): Indicates if the data includes radius/area information.
    radii (str): Column name for radius data.
    """
    try:
        altitude = int(altitude)
        tilt = int(tilt)
        linger = float(linger)
        kml = simplekml.Kml()
        tour = kml.newgxtour(name="Fetch Tour")
        playlist = tour.newgxplaylist()

        # Ensure that 'longitude', 'latitude', and 'time' columns are present
        if 'LONGITUDE' not in df.columns or 'LATITUDE' not in df.columns:
            raise ValueError("DataFrame must contain 'LONGITUDE' and 'LATITUDE' columns.")
        
        # Convert the 'TIME' column to datetime objects if present
        if time_column is not None:
            try:
                df[time_column] = pandas.to_datetime(df[time_column])
            except ValueError:
                df[time_column] = pandas.to_datetime(df[time_column], utc=True)
                df[time_column] = df[time_column].dt.tz_convert('UTC')
        
        # Iterate through the points in the DataFrame
        for idx, row in df.iterrows():
            try:
                lon, lat = row['LONGITUDE'], row['LATITUDE']
                description_lines = [f"{key}: {value}" for key, value in row.items()]
                description = "\n".join(description_lines)
                
                placemark = kml.newpoint(name=f"{row[time_column]}" if time_column else f"{row['LATITUDE']}, {row['LONGITUDE']}", coords=[(lon, lat)], description=description)
                placemark.style.iconstyle.icon.href = selected_icon[icon]

                if footprint and radii:
                    rad = row[radii]
                    polycircle = polycircles.Polycircle(latitude=float(lat),
                                                        longitude=float(lon),
                                                        radius=float(rad),
                                                        number_of_vertices=72)
                    pol = kml.newpolygon(name=f"{lat}, {lon}, {rad}", outerboundaryis=polycircle.to_kml())
                    pol.style.polystyle.color = get_footprint_color(icon_Color=icon)
                
                # Add a camera or look-at point for the tour
                flyto = playlist.newgxflyto(gxduration=3.0)
                flyto.camera.longitude = lon
                flyto.camera.latitude = lat
                flyto.camera.altitude = altitude
                flyto.camera.heading = 0
                flyto.camera.tilt = tilt
                flyto.camera.roll = 0
                
                # Add the time and date
                if time_column is not None:
                    flyto.when = row[time_column].isoformat() # Convert datetime to ISO format
            
                # Optionally, you can add a wait period between points
                playlist.newgxwait(gxduration=linger)  # Wait for the specified linger duration
            
            except AttributeError as e:
                print(f"Error at index {idx}: {e}")
            except TypeError as e:
                print(f"Error at index {idx}: {e}")

        # Save the KML to the specified output file
        kml.save(output_file)
        print(f"KML file saved as {output_file}")
    except TypeError:
        st.error("Error creating KML tour. Check for errors in the data set.")

def create_kml(df_in, outfile):
    try:
        headers = df_in.columns.to_list()

        # Streamlit UI for selecting columns
        st.subheader("Design Your KML Map")
        icon = st.selectbox("Select Map Point Icon Style", options=icon_options)        

        label_for_icons = st.selectbox("Map Icon Labels", options=headers)
        
        footprint = st.checkbox("Data set includes radius/area information", value=False)
        radii = None
        if footprint:
            radii = st.selectbox("Radius/Distance-from-Point in Meters", options=headers)
        
        tour = st.checkbox("Include KML Tour", value=False)
        if tour:        # Tour Settings
            st.subheader("Design Tour Settings")
            there_are_dates = st.checkbox("Data set includes date/time information", value=False)
            if there_are_dates:
                time_column = st.selectbox("Date/Time Column", options=headers)
            else:
                time_column = None
            tour_altitude = st.selectbox("Tour Altitude (Meters)", options=['50','150', '250', '300', '750', '1500', '10000'], index=2)
            tour_linger_time = st.selectbox("Tour Linger Time (Seconds)", options=['1', '2', '3', '4', '5', '10', '15'], index=3)
            tour_tilt = st.selectbox("Tour Tilt", options=['0', '5', '10', '20'], index=1)

    except AttributeError:
        print("Attribute error on variable headers in createkml")
        st.error("Check for errors in column selection.")

    if st.button("Generate KML"):
        filename = "MITE_KML_Map" + datetime.datetime.now().strftime("%Y%m%d%H%M%S")
        if not filename:
            st.error("Map Name Required")
        else:
            kml = simplekml.Kml()
            Label = label_for_icons
            
            try:
                for idx, row in df_in.iterrows():
                    lon, lat = row['LONGITUDE'], row['LATITUDE']
                    description_lines = [f"{key}: {value}" for key, value in row.items()]
                    descript = "\n".join(description_lines)      
                    lab = row[Label]
                    long = re.findall(r'([0-9.-]+)', str(lon))[0]
                    lati = re.findall(r'([0-9.-]+)', str(lat))[0]

                    point = kml.newpoint(name=lab, coords=[(float(long), float(lati))], description=descript)
                    point.style.iconstyle.icon.href = selected_icon[icon]

                    if footprint and radii:
                        rad = row[radii]
                        polycircle = polycircles.Polycircle(latitude=float(lati),
                                                           longitude=float(long),
                                                           radius=float(rad),
                                                           number_of_vertices=72)

                        pol = kml.newpolygon(name=f"{lati}, {long}, {rad}", outerboundaryis=polycircle.to_kml())
                        pol.style.polystyle.color = get_footprint_color(icon_Color=icon)
            except Exception as e:
                st.error(f"Error generating KML: {e}")

            if not tour:
                # Generate normal KML file
                kml.save(outfile)
                with open(outfile, 'rb') as f:
                    kml_data = f.read()

                st.download_button("Download KML", data=kml_data, file_name="Fetch_KML_Download.kml")

            if tour:
                # Generate the KML tour file
                tourfile = 'tour.kml'
                create_kml_tour(df=df_in, output_file=tourfile, altitude=tour_altitude, tilt=tour_tilt, linger=tour_linger_time, time_column=time_column, icon=icon, footprint=footprint, radii=radii)
                with open(tourfile, 'rb') as f:
                    tour_data = f.read()

                st.download_button("Download KML Tour", data=tour_data, file_name="Fetch_KML_Tour.kml")

            #st.success(f"KML file has been created. Click below to download.")


def time_range_slider(in_df):
 ## Range selector
    try:
        in_df[datetime_Column] = pandas.to_datetime(in_df[datetime_Column])
    except ValueError:          # This is happening on the GPX inputs
        in_df[datetime_Column] = pandas.to_datetime(in_df[datetime_Column], utc=True)
        in_df[datetime_Column] = in_df[datetime_Column].dt.tz_convert('UTC')

    try:
        format = 'YYYY-MM-DD'  # format output
        start_date = min(in_df[datetime_Column]).to_pydatetime()    # get start date of data frame
        end_date = max(in_df[datetime_Column]).to_pydatetime()      # get end date of data frame
        slider = st.slider('Select Date (YYYY-MM-DD)', min_value=start_date, value=(start_date,end_date) ,max_value=end_date, format=format)
        return slider   #kicks out start and end datetime
    except TypeError:
        st.error("slider error")

def time_filter(in_df, date_column):
    try:
        starting, ending = time_range_slider(in_df=in_df)
        sorted = in_df.sort_values(by=date_column)
        # print(sorted)
        col1, col2, col3, col4 = st.columns(4)
        with col1:
                start_date = st.date_input("Start Date",value=starting)     
        with col2:
                start_time = st.time_input("Start Time", value=datetime.time(0, 00, 00))
        with col3:
                end_date = st.date_input("End Date",value=ending)
        with col4:
                end_time = st.time_input("End Time", value=datetime.time(23, 59, 59))
        first_is = str(start_date) + " " + str(start_time)
        last_is = str(end_date) + " " + str(end_time)
        selected_time = sorted[(sorted[date_column] > first_is) & (sorted[date_column] < last_is)]
        st.markdown(":orange[Filtered Records:]  " + str(len(selected_time.index)))
        st.table(selected_time)
        return selected_time
    except parser.ParserError:
        st.error("Select column with Date/Time data.")

def declutterer(in_df, date_column):
    # resample every N minutes to get a mean value for lat and long.
    #     Sample Frequency cheatsheet
    # B         business day frequency
    # C         custom business day frequency (experimental)
    # D         calendar day frequency
    # W         weekly frequency
    # M         month end frequency
    # SM        semi-month end frequency (15th and end of month)
    # BM        business month end frequency
    # CBM       custom business month end frequency
    # MS        month start frequency
    # SMS       semi-month start frequency (1st and 15th)
    # BMS       business month start frequency
    # CBMS      custom business month start frequency
    # Q         quarter end frequency
    # BQ        business quarter endfrequency
    # QS        quarter start frequency
    # BQS       business quarter start frequency
    # A         year end frequency
    # BA, BY    business year end frequency
    # AS, YS    year start frequency
    # BAS, BYS  business year start frequency
    # BH        business hour frequency
    # H         hourly frequency
    # T, min    minutely frequency
    # S         secondly frequency
    # L, ms     milliseconds
    # U, us     microseconds
    # N         nanoseconds
    in_df[date_column] = pandas.to_datetime(in_df[date_column])
    declutter_data = in_df.set_index(date_column)
    Time_intervals = { "Year": "A", "Month": "M", "Week": "W", "Day": "D", "Hour" : "H", "Minute": "T","Second": "S"}
    spot1, spot2, spot3, spot4 = st.columns(4)
    with spot1:
        count_of_time = st.number_input("Interval Count", min_value=1, max_value=60,)
    with spot2:
        choose_interval = st.selectbox("Interval Type", options=list(Time_intervals.keys()))
    resample_Rate = str(count_of_time) + Time_intervals[choose_interval]
    print(resample_Rate)
    declutter_data = declutter_data.resample(resample_Rate).agg({'LATITUDE': 'mean', 'LONGITUDE': 'mean'})
    declutter_data = declutter_data[declutter_data['LATITUDE'].notna()]
    st.markdown(":orange[Number of Averaged Locations:]  " + str(len(declutter_data.index)))
    # declutter_data = in_df.resample("5D").mean()
    return declutter_data
########################################
#### In Progress



########################################

####    Main Page   ####
notices = st.empty()            #   Places notifications at the top of the screen
# filename = st.text_input(":red[Provide Map Name*]",)
uploaded_file = st.file_uploader("Choose a CSV, TXT (Comma Seperated), TSV, Excel, or GPX file", type=["csv","txt","tsv","xlsx","xls","gpx"], accept_multiple_files=False)

if uploaded_file != None:
    # filename = st.text_input(":red[Provide Map Name*]",)
    with st.expander("Manage Ingested Data"):
        tabi, tabii, tabiii = st.tabs(["Review Ingest Data", "Time Filter", "Declutter"])
        with tabi:
            lines_t0_remove = st.slider(label="Number of Rows to Remove from Start of Table      (First line must include 'Latitude' and 'Longitude')", min_value=0, max_value=10)
            if uploaded_file != None:   
                suggested_encoding = get_file_encoding(uploaded_file)       #   block attempts to find csv encoding and allow manual choice
                encode_options = st.radio(label="Encoding Options", options=["Use Suggested Encoding: " + str(suggested_encoding['encoding']), "Use Manual Encoding Selection"],horizontal=True)
                if encode_options == "Use Suggested Encoding: " + str(suggested_encoding['encoding']):
                    selected_encoding = suggested_encoding['encoding']
                if encode_options == "Use Manual Encoding Selection":       
                    selected_encoding = st.selectbox("Choose File Encoding",options=["utf-8", 'utf-8-sig', 'utf-16', 'ISO-8859-1'])
                uploaded_file.seek(0)       #refresh action
                outFile = KML_output_file("MITE_KML_Map"+str(now))

                # print(outFile)
                try:
                    get_headings, preview_data = make_dataframe(uploaded_file, outfile=outFile)
                except UnboundLocalError:
                    pass
                except TypeError:
                    st.error("Keep altering the row selection...")

        with tabii:
            filterbytime = st.checkbox("Filter by Date/Time")
            if filterbytime == True:
                datetime_Column = st.selectbox("Select Date/Time Column", options=preview_data.columns)
                preview_data = time_filter(preview_data,date_column=datetime_Column)
                print(preview_data)
                
        with tabiii:
            declutter_dis = st.checkbox("Consolidate points to an average location based on selected time interval.")
            if declutter_dis == True:
                try:
                    datetim_Column = st.selectbox("Choose Date/Time Column", options=preview_data.columns)
                except AttributeError:
                    st.error("Select column with Date/Time data.")
                try:
                    preview_data = declutterer(preview_data, date_column=datetim_Column)
                    print(preview_data)
                except Exception:
                    st.error("Select date/time column")

if uploaded_file == None:
    tabA, tabB = st.tabs(["Create Geofence", "IP Address Mapping"])
    with tabA:
        make_geofence_map()
    with tabB:
        make_IPaddress_Map()
        

if uploaded_file != None:
    if declutter_dis or filterbytime == True:
        st.markdown(":orange[FILTERS ARE IN EFFECT]")
    tab1, tab2, tab3 = st.tabs(["Preview/KML Map", "Analysis Maps", "Create Geofence"])
    with tab1:
        try:
            st.map(preview_data)
        except TypeError:
            st.error("Ensure you have correct settings in Manage Ingested Data and Date/Time Filtering. Remove any non-numeric characters from your Lat/Long columns.")  
        except Exception:
            # st.error("Check your data input. Hints - Must have Latitude and Longitude columns. Remove unnecessary header rows.")
            st.error("Error: Please review your data set and ensure it is formatted correctly. Must include 'Latitude' and 'Longitude' columns. Remove any unnecessary header rows.")
 
        # icon = st.selectbox("Select Map Point Icon Style", options=icon_options)
        # footprint = st.checkbox("Dataset includes radius/area information",)
        

        # KML = st.button("GENERATE KML")
        st.markdown("---")
        try:
            create_kml(df_in=preview_data,outfile=outFile)
        except Exception as e:
            st.error(f"Error generating KML: {e}")
        
    with tab2:
        # try:
        make_map(preview_data)
        # except AttributeError:
        #     st.error("Check that your data has Latitude and Longitude columns")
    with tab3:
        make_geofence_map()
    
# add a button to open a popup window that will contain hyperlinks
st.markdown("---")

with st.expander("Privacy Statement and API Use"):
    st.write("""
    ## Data Privacy Statement and API Usage Information
    
    We take your privacy seriously. North Loop Consulting will only have temporary access to small portions of data that may be involved in error reporting.  
    This data will not be stored for any period longer than needed to identify and correct any issues, if at all.
                
    We make use of a third party company, Streamlit, to provide hosting for Fetch.  
    For more information about Streamlit and their handling of user data, please refer to their [Privacy Policy](https://streamlit.io/privacy-policy).
    
    For specific information about how Streamlit handles data sets you have uploaded as files, please refer to their 
    [documents on file uploads](https://docs.streamlit.io/knowledge-base/using-streamlit/where-file-uploader-store-when-deleted).
    
    It is always best to avoid uploading sensitive data to any online service. Please do not upload any data that may contain personal identifiable information or sensitive data.

    Fetch is intended to be a free tool available to everyone.  To do this, free resources are used to return information like IP address data.  There are caps on this free usage.  You may run into periods where that cap has been met and these resources are not available. If you would like to explore financial support for the tool to expand these capabilities, I am open to the conversation. Just reach out via the Contact Page on our site.   
    """)
st.markdown(":orange[© 2024 North Loop Consulting - Fetch_v3.8]")