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import streamlit as st
import pandas as pd
import numpy as np
from sklearn.neighbors import KNeighborsRegressor
from geopy.distance import geodesic
import googlemaps
from geopy.exc import GeocoderTimedOut
from streamlit_folium import st_folium
import folium
from branca.colormap import LinearColormap
import base64
from io import BytesIO
import sys
import pydeck as pdk

# Print the Python version
print("Python version")
print(sys.version)
print("Version info.")
print(sys.version_info)



# Function to add heatmap layer to folium map
def add_heatmap_layer(map_obj, data, column_name, colormap_name, radius=15):
    heat_data = data[['latitude', 'longitude', column_name]].dropna()
    heat_layer = folium.FeatureGroup(name=f'Variável - {column_name}')

    cmap = LinearColormap(colors=['blue', 'white', 'red'], vmin=heat_data[column_name].min(), vmax=heat_data[column_name].max())

    for index, row in heat_data.iterrows():
        folium.CircleMarker(
            location=[row['latitude'], row['longitude']],
            radius=radius,
            fill=True,
            fill_color=cmap(row[column_name]),
            fill_opacity=0.7,
            color='black',
            weight=0.5,
            popup=f"{column_name}: {row[column_name]:.2f}"  # Fix here
        ).add_to(heat_layer)

    heat_layer.add_to(map_obj)
    
# Function to calculate distance in meters between two coordinates
def calculate_distance(lat1, lon1, lat2, lon2):
    coords_1 = (lat1, lon1)
    coords_2 = (lat2, lon2)
    return geodesic(coords_1, coords_2).meters

def knn_predict(df, target_column, features_columns, k=5):
    # Separate features and target variable
    X = df[features_columns]
    y = df[target_column]

    # Check if there is enough data for prediction
    if len(X) < k:
        return np.zeros(len(X))  # Return an array of zeros if there isn't enough data

    # Create KNN regressor
    knn = KNeighborsRegressor(n_neighbors=k)

    # Fit the model
    knn.fit(X, y)

    # Use the model to predict target_column for the filtered_data
    predictions = knn.predict(df[features_columns])

    return predictions

# Set wide mode
st.set_page_config(layout="wide")

# Set dark theme
st.markdown(
    """
    <style>
        @font-face {font-family: 'Quicksand';
        src: url('font/Quicksand-VariableFont_wght.ttf') format('truetype');

        }
        body {
            color: white;
            background-color: #1e1e1e;
            font-family: 'Quicksand', sans-serif;
        }
        .st-df-header, .st-df-body, .st-df-caption {
            color: #f8f9fa;  /* Bootstrap table header text color */
        }
        .st-eb {
            background-color: #343a40;  /* Streamlit exception box background color */
        }
    </style>
    """,
    unsafe_allow_html=True
)


# Create a DataFrame with sample data
data = pd.read_excel('data_nexus.xlsx')

# Initialize variables to avoid NameError
radius_visible = True
custom_address_initial = 'Centro, Lajeado - RS, Brazil'  # Initial custom address
#custom_lat = data['latitude'].median()
custom_lat = -29.45880114339262
#custom_lon = data['longitude'].median()
custom_lon = -51.97011580843118
radius_in_meters = 150000
filtered_data = data  # Initialize with the entire dataset

# Calculate a zoom level based on the maximum distance
zoom_level = 13

# Set font to 'Quicksand' for title_html
title_html = """
        <style>
        @font-face {font-family: 'Quicksand';
        src: url('font/Quicksand-VariableFont_wght.ttf') format('truetype');
        }
        body {{
            font-family: 'Quicksand', sans-serif;
        }}
    </style>
    <span style='color: #566f71; font-size: 50px;'>aval</span>
    <span style='color: #edb600; font-size: 50px;'>ia</span>
    <span style='color: #566f71; font-size: 50px;'>.se</span>
    """

# Set font to 'Quicksand' for factor_html
factor_html = """
    <style>
        @font-face {font-family: 'Quicksand';
        src: url('font/Quicksand-VariableFont_wght.ttf') format('truetype');
        }
        body {{
            font-family: 'Quicksand', sans-serif;
        }}
    </style>
    <a href='https://huggingface.co/spaces/DavidSB/avaliaFACTOR' target='_blank' style='text-decoration: none; color: inherit;'>
    <span style='color: #566f71; font-size: 20px;'>aval</span>
    <span style='color: #edb600; font-size: 20px;'>ia</span>
    <span style='color: #566f71; font-size: 20px;'>.FACTOR</span>
"""

# Set font to 'Quicksand' for evo_html
evo_html = """
    <style>
        @font-face {font-family: 'Quicksand';
        src: url('font/Quicksand-VariableFont_wght.ttf') format('truetype');
        }
        body {{
            font-family: 'Quicksand', sans-serif;
        }}
    </style>
    <a href='https://huggingface.co/spaces/DavidSB/avalia.EVO' target='_blank' style='text-decoration: none; color: inherit;'>
    <span style='color: #566f71; font-size: 20px;'>aval</span>
    <span style='color: #edb600; font-size: 20px;'>ia</span>
    <span style='color: #566f71; font-size: 20px;'>.EVO</span>
"""


# Create a sidebar for controls
with st.sidebar:
    st.markdown(title_html, unsafe_allow_html=True)

    # Add a dropdown for filtering "Fonte"
    selected_fonte = st.selectbox('Finalidade', data['Fonte'].unique(), index=data['Fonte'].unique().tolist().index('Venda'))
    data = data[data['Fonte'] == selected_fonte]

    # Add a dropdown for filtering "Tipo"
    selected_tipo = st.selectbox('Tipo de imóvel', data['Tipo'].unique(), index=data['Tipo'].unique().tolist().index('Apartamento'))
    data_tipo = data[data['Tipo'] == selected_tipo]
    
    custom_address = st.text_input('Informe o endereço', custom_address_initial)
    radius_visible = True  # Show radius slider for custom coordinates

    gmaps = googlemaps.Client(key='AIzaSyDoJ6C7NE2CHqFcaHTnhreOfgJeTk4uSH0')  # Replace with your API key

    try:
        # Ensure custom_address ends with " - RS, Brazil"
        custom_address = custom_address.strip()  # Remove leading/trailing whitespaces
        if not custom_address.endswith(" - RS, Brazil"):
            custom_address += " - RS, Brazil"

        location = gmaps.geocode(custom_address)[0]['geometry']['location']
        custom_lat, custom_lon = location['lat'], location['lng']
    except (IndexError, GeocoderTimedOut):
        st.error("Erro: Não foi possível geocodificar o endereço fornecido. Por favor, verifique e tente novamente.")

    # Conditionally render the radius slider
    if radius_visible:
        radius_in_meters = st.number_input('Selecione raio (em metros)', min_value=0, max_value=100000, value=2000)

    # Add sliders to filter data based
    #atotal_range = st.slider('Área Total', float(data_tipo['Atotal'].min()), float(data_tipo['Atotal'].max()), (float(data_tipo['Atotal'].min()), float(data_tipo['Atotal'].max())), step=.1 if data_tipo['Atotal'].min() != data_tipo['Atotal'].max() else 0.1)
    #apriv_range = st.slider('Área Privativa', float(data_tipo['Apriv'].min()), float(data_tipo['Apriv'].max()), (float(data_tipo['Apriv'].min()), float(data_tipo['Apriv'].max())), step=.1 if data_tipo['Apriv'].min() != data_tipo['Apriv'].max() else 0.1)

    # Create two columns for Área Total inputs
    col1, col2 = st.columns(2)
    with col1:
        atotal_min = st.number_input('Área Total mínima', 
                                     min_value=float(data_tipo['Atotal'].min()), 
                                     max_value=float(data_tipo['Atotal'].max()), 
                                     value=float(data_tipo['Atotal'].min()),
                                     step=0.1)
    with col2:
        atotal_max = st.number_input('Área Total máxima', 
                                     min_value=float(data_tipo['Atotal'].min()), 
                                     max_value=float(data_tipo['Atotal'].max()), 
                                     value=float(data_tipo['Atotal'].max()),
                                     step=0.1)

    # Create two columns for Área Privativa inputs
    col3, col4 = st.columns(2)
    with col3:
        apriv_min = st.number_input('Área Privativa mínima', 
                                    min_value=float(data_tipo['Apriv'].min()), 
                                    max_value=float(data_tipo['Apriv'].max()), 
                                    value=float(data_tipo['Apriv'].min()),
                                    step=0.1)
    with col4:
        apriv_max = st.number_input('Área Privativa máxima', 
                                    min_value=float(data_tipo['Apriv'].min()), 
                                    max_value=float(data_tipo['Apriv'].max()), 
                                    value=float(data_tipo['Apriv'].max()),
                                    step=0.1)

    
    #data_tipo = data_tipo[(data_tipo['Atotal'].between(atotal_range[0], atotal_range[1])) &
            #(data_tipo['Apriv'].between(apriv_range[0], apriv_range[1]))]
        
    data_tipo = data_tipo[(data_tipo['Atotal'].between(atotal_min, atotal_max)) &
            (data_tipo['Apriv'].between(apriv_min, apriv_max))]
    
# Links to other apps at the bottom of the sidebar
#st.sidebar.markdown(factor_html, unsafe_allow_html=True)
#st.sidebar.markdown(evo_html, unsafe_allow_html=True)

filtered_data = data_tipo[data_tipo.apply(lambda x: calculate_distance(x['latitude'], x['longitude'], custom_lat, custom_lon), axis=1) <= radius_in_meters]
filtered_data = filtered_data.dropna()  # Drop rows with NaN values

# Add a custom CSS class to the map container
st.markdown(f"""<style>
.map {{
  width: 100%;
  height: 100vh;
}}
</style>""", unsafe_allow_html=True)

# Determine which area feature to use for prediction
filtered_data['area_feature'] = np.where(filtered_data['Apriv'] != 0, filtered_data['Apriv'], filtered_data['Atotal'])

# Define the target column based on conditions
filtered_data['target_column'] = np.where(filtered_data['Vunit_priv'] != 0, filtered_data['Vunit_priv'], filtered_data['Vunit_total'])

# Apply KNN and get predicted target values
predicted_target = knn_predict(filtered_data, 'target_column', ['latitude', 'longitude', 'area_feature'])  # Update with your features

# Add predicted target values to filtered_data
filtered_data['Predicted_target'] = predicted_target


with st.container():
    # Define a PyDeck view state for the initial map view
    view_state = pdk.ViewState(latitude=filtered_data['latitude'].mean(), longitude=filtered_data['longitude'].mean(), zoom=zoom_level)

    # Define a PyDeck layer for plotting
    layer = pdk.Layer(
        "ScatterplotLayer",
        filtered_data,
        get_position=["longitude", "latitude"],
        get_color="[237, 181, 0, 160]",  # RGBA color for light orange, adjust opacity with the last number
        get_radius=100,  # Adjust dot size as needed
    )

    # Create a PyDeck map using the defined layer and view state
    deck_map = pdk.Deck(layers=[layer], initial_view_state=view_state, map_style="mapbox://styles/mapbox/light-v9")

    # Display the map in Streamlit
    st.pydeck_chart(deck_map)
    #st.map(filtered_data, zoom=zoom_level, use_container_width=True)
    st.write("Dados:", filtered_data)  # Debug: Print filtered_data

    if st.button('Baixar planilha'):
        st.write("Preparando...")
        # Set up the file to be downloaded
        output_df = filtered_data

        # Create a BytesIO buffer to hold the Excel file
        excel_buffer = BytesIO()

        # Convert DataFrame to Excel and save to the buffer
        with pd.ExcelWriter(excel_buffer, engine="xlsxwriter") as writer:
            output_df.to_excel(writer, index=False, sheet_name="Sheet1")

        # Reset the buffer position to the beginning
        excel_buffer.seek(0)

        # Create a download link
        b64 = base64.b64encode(excel_buffer.read()).decode()
        href = f'<a href="data:application/vnd.openxmlformats-officedocument.spreadsheetml.sheet;base64,{b64}" download="sample_data.xlsx">Clique aqui para baixar a planilha</a>'
        #st.markdown(href, unsafe_allow_html=True)

        # Use st.empty() to create a placeholder and update it with the link
        download_placeholder = st.empty()
        download_placeholder.markdown(href, unsafe_allow_html=True)
        

    def add_heatmap_layer(folium_layermap, data, column, colormap):
        heatmap_layer = folium.plugins.HeatMap(data=data[['latitude', 'longitude', column]],
                                               min_opacity=0.5,
                                               max_zoom=18,
                                               radius=25, blur=15, 
                                               gradient=None, 
                                               overlay=True, 
                                               control=True, 
                                               show=True,
                                               colormap=colormap)
        folium_layermap.add_child(heatmap_layer)

    # Create a Folium map centered on a specific location
    folium_layermap = folium.Map(location=[custom_lat, custom_lon], zoom_start=12, tiles='Stamen Toner')

    # Add grayscale tiles from OpenStreetMap
    folium.TileLayer('https://tiles.stadiamaps.com/tiles/alidade_smooth/{z}/{x}/{y}{r}.png', 
                     attr='© Stadia Maps', 
                     name='grayscale').add_to(folium_layermap)

    # Add heatmap layers for 'Valor_Urb', 'Valor_Eqp', and 'RENDA'
    add_heatmap_layer(folium_layermap, filtered_data, 'Valor_Urb', 'RdBu_r')
    add_heatmap_layer(folium_layermap, filtered_data, 'Valor_Eqp', 'RdBu_r')
    add_heatmap_layer(folium_layermap, filtered_data, 'RENDA', 'RdBu_r')

    # Add layer control
    folium.LayerControl().add_to(folium_layermap)

    # Display the map using st_folium
    st.folium_chart(folium_layermap, width=1200, height=600)

k_threshold = 5

# Function to perform bootstrap on the predicted target values
def bootstrap_stats(bound_data, num_samples=1000):
    # Reshape the predicted_target array
    bound_data = np.array(bound_data).reshape(-1, 1)

    # Bootstrap resampling
    bootstrapped_means = []
    for _ in range(num_samples):
        bootstrap_sample = np.random.choice(bound_data.flatten(), len(bound_data), replace=True)
        bootstrapped_means.append(np.mean(bootstrap_sample))

    # Calculate lower and higher bounds
    lower_bound = np.percentile(bootstrapped_means, 16.)
    higher_bound = np.percentile(bootstrapped_means, 84.)

    return lower_bound, higher_bound

# Apply KNN and get predicted Predicted_target values
predicted_target = knn_predict(filtered_data, 'Predicted_target', ['latitude', 'longitude', 'area_feature'])

# Check if there are predictions to display
if 'Predicted_target' in filtered_data.columns and not np.all(predicted_target == 0):

    # Apply bootstrap - bounds
    lower_bound, higher_bound = bootstrap_stats(filtered_data['target_column'])

    mean_value = np.mean(filtered_data['Predicted_target'])

    # Display the results with custom styling
    st.markdown("## **Algoritmo **")
    st.write(f"Valor médio (Reais/m²) para as características selecionadas: ${mean_value:.2f}$ Reais")
    st.write(f"Os valores podem variar entre ${lower_bound:.2f}$ e ${higher_bound:.2f}$ Reais, dependendo das características dos imóveis.")
else:
    st.warning(f"**Dados insuficientes para inferência do valor. Mínimo necessário:** {k_threshold}")