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import gradio as gr
import torch
from torch import nn
import numpy as np
import pandas as pd
from utils2 import compute_features, DATASET_COLUMNS
from scipy.stats import nbinom
from xgboost import XGBRegressor
import json
# class NegBinomialModel(nn.Module):
# def __init__(self, in_features):
# super().__init__()
# self.linear = nn.Linear(in_features, 1)
# self.alpha = nn.Parameter(torch.tensor(0.5))
# def forward(self, x):
# # safer activation than exp()
# mu = torch.exp(torch.clamp(self.linear(x), min=-5, max=5))
# alpha = torch.clamp(self.alpha, min=1e-3, max=10)
# return mu.squeeze(), alpha
# model = NegBinomialModel(12)
# model.load_state_dict(torch.load("model_weights.pt", map_location='cpu'))
# model.eval()
# MU_BANKS = 2.6035915713614286
# STD_BANKS = 3.0158890435512125
# with open("xgb_model(1).json", "r") as f:
# params = json.load(f)
xgb_model = XGBRegressor()
xgb_model.load_model("xgb_model(2).json")
def predict_score(lat, lon):
# Convert input to tensor
# inputs = torch.tensor([[lat, lon]], dtype=torch.float32)
inputs = compute_features((lat,lon))
print("[INPUTS]", inputs)
num_banks = inputs.pop("num_banks_in_radius", 0)
input_dict = inputs.copy()
inputs = torch.tensor(list(inputs.values()), dtype=torch.float32)
# # Get model output
# with torch.no_grad():
# mu_pred, alpha = model(inputs)
# # Unpack into respective values
# mu_pred = mu_pred.numpy().flatten()
mu_pred2 = xgb_model.predict(inputs.unsqueeze(0).numpy())
# r = 1/alpha
# p = r / (r + mu_pred)
# # Compute pmf and mode
# k_mode = int((r - 1) * (1 - p) / p) # mode of NB
# p_k = nbinom.pmf(num_banks, r, p)
# p_mode = nbinom.pmf(k_mode, r, p)
# # Score normalized 0–100
# score = (p_k / p_mode) * 100
# score = np.clip(score, 0, 100)
# diff = (num_banks - mu_pred) / (mu_pred + 1e-6)
# # score = (1 - np.tanh(diff))
# print("[TANH]", np.tanh(diff))
# diff = mu_pred2 - num_banks
# score = 100 / (1 + np.exp(-alpha * diff))
# score = np.abs(1 + np.tanh(diff)) / 2 * 100
# score = (1 * np.abs(mu_pred2 + 0.1)) * 100
# score = np.sigmoid(mu_pred2 - num_banks + 0.1) * 100
score = 100 / (1 + np.exp(num_banks - mu_pred2))
# You can apply any post-processing here
return (
round(float(score), 3),
num_banks,
# round(float(mu_pred), 3),
round(float(mu_pred2), 3),
# round(float(log_score),3)
# "Normal Score": round(float(normal_score), 3),
input_dict["total_amenities"],
*[v for k,v in input_dict.items() if k[:3] == "num"]
)
# ======== Gradio Interface ========
interface = gr.Interface(
fn=predict_score,
inputs=[
gr.Number(label="Latitude"),
gr.Number(label="Longitude"),
],
outputs=[
gr.Number(label="Score (0 - 100)"),
gr.Number(label="Current ATMs"),
# gr.Number(label="Number of Ideal Banks (Negative Binomial)"),
gr.Number(label="Ideal ATMs (XGBoost)"),
# gr.Number(label="Log Score Probability"),
gr.Number(label="Total Amenities"),
*[gr.Number(label=x) for x in DATASET_COLUMNS]
# gr.Number(label="Dining and Drinking"),
# gr.Number(label="Community and Government"),
# gr.Number(label="Retail"),
# gr.Number(label="Business and Professional Services"),
# gr.Number(label="Landmarks and Outdoors"),
# gr.Number(label="Arts and Entertainment"),
# gr.Number(label="Health and Medicine"),
# gr.Number(label="Travel and Transportation"),
# gr.Number(label="Sports and Recreation"),
# gr.Number(label="Event"),
],
title="Bank Location Scoring Model",
description="Enter latitude and longitude to get the predicted score, number of banks, and normalized score.",
)
interface.launch()
# import gradio as gr
# import torch
# from torch import nn
# import numpy as np
# import pandas as pd
# from utils import compute_features
# from scipy.stats import nbinom
# from xgboost import XGBRegressor
# import json
# class NegBinomialModel(nn.Module):
# def __init__(self, in_features):
# super().__init__()
# self.linear = nn.Linear(in_features, 1)
# self.alpha = nn.Parameter(torch.tensor(0.5))
# def forward(self, x):
# # safer activation than exp()
# mu = torch.exp(torch.clamp(self.linear(x), min=-5, max=5))
# alpha = torch.clamp(self.alpha, min=1e-3, max=10)
# return mu.squeeze(), alpha
# model = NegBinomialModel(12)
# model.load_state_dict(torch.load("model_weights(1).pt", map_location='cpu'))
# model.eval()
# # MU_BANKS = 2.6035915713614286
# # STD_BANKS = 3.0158890435512125
# # with open("xgb_model(1).json", "r") as f:
# # params = json.load(f)
# xgb_model = XGBRegressor()
# xgb_model.load_model("xgb_model(1).json")
# def predict_score(lat, lon):
# # Convert input to tensor
# # inputs = torch.tensor([[lat, lon]], dtype=torch.float32)
# inputs = compute_features((lat,lon))
# print("[INPUTS]", inputs)
# num_banks = inputs.pop("num_banks_in_radius", 0)
# inputs = torch.tensor(list(inputs.values()), dtype=torch.float32)
# # Get model output
# with torch.no_grad():
# mu_pred, alpha = model(inputs)
# # Unpack into respective values
# mu_pred = mu_pred.numpy().flatten()
# mu_pred2 = xgb_model.predict(inputs.unsqueeze(0).numpy())
# # r = 1/alpha
# # p = r / (r + mu_pred)
# # # Compute pmf and mode
# # k_mode = int((r - 1) * (1 - p) / p) # mode of NB
# # p_k = nbinom.pmf(num_banks, r, p)
# # p_mode = nbinom.pmf(k_mode, r, p)
# # # Score normalized 0–100
# # score = (p_k / p_mode) * 100
# # score = np.clip(score, 0, 100)
# # diff = (num_banks - mu_pred) / (mu_pred + 1e-6)
# # # score = (1 - np.tanh(diff))
# # print("[TANH]", np.tanh(diff))
# diff = mu_pred - num_banks
# score = 100 / (1 + np.exp(-alpha * diff))
# score = np.abs(1 + np.tanh(diff)) / 2 * 100
# # score = (1 * np.abs(mu_pred + 0.1)) * 100
# # You can apply any post-processing here
# return (
# round(float(score), 3),
# num_banks,
# round(float(mu_pred), 3),
# round(float(mu_pred2), 3),
# # round(float(log_score),3)
# # "Normal Score": round(float(normal_score), 3),
# )
# # ======== Gradio Interface ========
# interface = gr.Interface(
# fn=predict_score,
# inputs=[
# gr.Number(label="Latitude"),
# gr.Number(label="Longitude"),
# ],
# outputs=[
# gr.Number(label="Score (0 - 100)"),
# gr.Number(label="Number of Current Banks"),
# gr.Number(label="Number of Ideal Banks (Negative Binomial)"),
# gr.Number(label="Number of Ideal Banks (XGBoost)"),
# # gr.Number(label="Log Score Probability"),
# ],
# title="Bank Location Scoring Model",
# description="Enter latitude and longitude to get the predicted score, number of banks, and normalized score.",
# )
# interface.launch()
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