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Mehak-Mazhar

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	# Gradio app: CSV -> Preprocessing -> Logistic Regression with hyperparameter tuning
	# Save this file as gradio_logreg_app.py and run: python gradio_logreg_app.py

	import io
	import pandas as pd
	import numpy as np
	import matplotlib.pyplot as plt
	from sklearn.model_selection import train_test_split, GridSearchCV
	from sklearn.preprocessing import StandardScaler, OneHotEncoder
	from sklearn.impute import SimpleImputer
	from sklearn.compose import ColumnTransformer
	from sklearn.pipeline import Pipeline
	from sklearn.linear_model import LogisticRegression
	from sklearn.metrics import accuracy_score, confusion_matrix, classification_report, roc_auc_score
	import gradio as gr
	def load_csv(file_obj):
	# Case: path string
	if isinstance(file_obj, str):
	try:
	return pd.read_csv(file_obj), None
	except Exception as e_csv:
	try:
	return pd.read_excel(file_obj), None
	except Exception as e_xls:
	return None, f"Failed to read file from path. CSV error: {e_csv} / Excel error: {e_xls}"

	# Case: file-like object
	if hasattr(file_obj, "read"):
	file_obj.seek(0)
	try:
	return pd.read_csv(file_obj), None
	except Exception as e_csv:
	file_obj.seek(0)
	try:
	return pd.read_excel(file_obj), None
	except Exception as e_xls:
	return None, f"Failed to read file object. CSV error: {e_csv} / Excel error: {e_xls}"

	return None, "Unsupported file type."


	def on_upload(file):
	if file is None:
	return gr.Dropdown.update(choices=[]), "No file uploaded", None

	df, err = load_csv(file)
	if err:
	return gr.Dropdown.update(choices=[]), f"Error: {err}", None

	cols = df.columns.tolist()
	default_target = cols[-1] if cols else None
	return gr.Dropdown.update(choices=cols, value=default_target), f"Loaded {len(df)} rows, {len(cols)} columns", df


	# Helper: build preprocessing + model pipeline
	def build_pipeline(df, target_col, impute_strategy, apply_scaling, encode_categorical):
	X = df.drop(columns=[target_col])
	numeric_cols = X.select_dtypes(include=[np.number]).columns.tolist()
	categorical_cols = X.select_dtypes(exclude=[np.number]).columns.tolist()

	transformers = []
	if numeric_cols:
	num_transformers = []
	if impute_strategy != 'none':
	num_transformers.append(('imputer', SimpleImputer(strategy=impute_strategy)))
	if apply_scaling:
	num_transformers.append(('scaler', StandardScaler()))
	if num_transformers:
	from sklearn.pipeline import make_pipeline
	transformers.append(('num', make_pipeline(*[t[1] for t in num_transformers]), numeric_cols))

	if categorical_cols and encode_categorical:
	cat_transformer = Pipeline(steps=[('imputer', SimpleImputer(strategy='most_frequent')),
	('ohe', OneHotEncoder(handle_unknown='ignore', sparse=False))])
	transformers.append(('cat', cat_transformer, categorical_cols))

	if transformers:
	preprocessor = ColumnTransformer(transformers=transformers, remainder='passthrough')
	else:
	preprocessor = 'passthrough'

	pipe = Pipeline(steps=[('preproc', preprocessor), ('clf', LogisticRegression(max_iter=200))])
	return pipe


	# Training function
	def train_model(df, target_col, test_size, random_state, impute_strategy, apply_scaling, encode_categorical,
	use_grid, c_min, c_max, c_steps, penalties, solver, cv_folds, max_iter, n_jobs):
	# Basic checks
	if df is None:
	return "No data loaded", None, None, None
	if target_col not in df.columns:
	return f"Target column '{target_col}' not found", None, None, None

	# Drop rows where target is missing
	data = df.copy()
	data = data.dropna(subset=[target_col])

	# If target is not numeric, try to encode it
	y = data[target_col]
	if y.dtype == object or y.dtype.name == 'category' or y.dtype == bool:
	y = pd.factorize(y)[0]

	X = data.drop(columns=[target_col])

	X_train, X_test, y_train, y_test = train_test_split(X, y, test_size=test_size, random_state=random_state, stratify=y if len(np.unique(y))>1 else None)

	pipe = build_pipeline(pd.concat([X_train, y_train], axis=1), target_col, impute_strategy, apply_scaling, encode_categorical)
	pipe.named_steps['clf'].max_iter = max_iter

	if use_grid:
	# build param grid for C and penalty
	C_values = np.linspace(c_min, c_max, int(max(1, c_steps)))
	param_grid = {}
	# penalty and solver interaction needs care
	selected_penalties = penalties if len(penalties)>0 else ['l2']
	param_grid['clf__C'] = C_values
	param_grid['clf__penalty'] = selected_penalties
	param_grid['clf__solver'] = [solver]

	gs = GridSearchCV(pipe, param_grid, cv=cv_folds, n_jobs=n_jobs, scoring='accuracy')
	gs.fit(X_train, y_train)
	best = gs.best_estimator_
	best_params = gs.best_params_
	model = best
	train_pred = model.predict(X_train)
	test_pred = model.predict(X_test)
	acc = accuracy_score(y_test, test_pred)
	report = classification_report(y_test, test_pred)
	cm = confusion_matrix(y_test, test_pred)
	extra = f"Best params: {best_params}"
	else:
	# set hyperparams from UI
	clf = pipe.named_steps['clf']
	try:
	clf.set_params(C=float((c_min+c_max)/2), penalty=penalties[0] if penalties else 'l2', solver=solver)
	except Exception:
	# fallback: set only C
	clf.set_params(C=float((c_min+c_max)/2))

	pipe.fit(X_train, y_train)
	model = pipe
	train_pred = model.predict(X_train)
	test_pred = model.predict(X_test)
	acc = accuracy_score(y_test, test_pred)
	report = classification_report(y_test, test_pred)
	cm = confusion_matrix(y_test, test_pred)
	extra = "Trained with provided hyperparameters"

	# Plot confusion matrix
	fig, ax = plt.subplots(figsize=(4,4))
	ax.imshow(cm, interpolation='nearest')
	ax.set_title('Confusion matrix')
	ax.set_xlabel('Predicted')
	ax.set_ylabel('Actual')
	for i in range(cm.shape[0]):
	for j in range(cm.shape[1]):
	ax.text(j, i, str(cm[i, j]), ha='center', va='center', color='white' if cm[i,j]>cm.max()/2 else 'black')
	plt.tight_layout()

	return f"Accuracy: {acc:.4f}\n{extra}", fig, report, model


	# Build Gradio interface
	with gr.Blocks(title="CSV -> Logistic Regression (with tuning)") as demo:
	gr.Markdown("""
	# CSV → Preprocessing → Logistic Regression
	1. Upload a CSV or Excel file.
	2. Select the target (label) column.
	3. Choose preprocessing options and hyperparameters.
	4. Train model and view accuracy, confusion matrix and classification report.
	""")

	with gr.Row():
	with gr.Column(scale=1):
	file_input = gr.File(label="Upload CSV/Excel file", file_types=['.csv', '.xls', '.xlsx'])
	load_status = gr.Textbox(label="File status", interactive=False)
	target_dropdown = gr.Dropdown(label="Select target column", choices=[], value=None)
	preview_button = gr.Button("Preview data")
	preview_output = gr.Dataframe(headers=None, interactive=False)

	with gr.Column(scale=1):
	gr.Markdown("Preprocessing")
	impute_radio = gr.Radio(['mean','median','most_frequent','constant','none'], value='mean', label='Numeric imputation (if needed)')
	scaler_checkbox = gr.Checkbox(label='Apply Standard Scaling', value=True)
	encode_checkbox = gr.Checkbox(label='One-Hot Encode categorical', value=True)

	gr.Markdown("Train / Test & Randomness")
	test_size = gr.Slider(0.05, 0.5, value=0.2, step=0.05, label='Test size')
	random_state = gr.Number(value=42, precision=0, label='Random state (int)')

	gr.Markdown("Logistic Regression hyperparams")
	use_grid = gr.Checkbox(label='Use GridSearchCV for hyperparameter tuning', value=True)
	c_min = gr.Number(value=0.01, label='C (min)')
	c_max = gr.Number(value=10.0, label='C (max)')
	c_steps = gr.Slider(1, 20, value=5, step=1, label='C steps (grid size)')
	penalties = gr.CheckboxGroup(['l1','l2','elasticnet','none'], label='Penalties to try (Grid only / or choose first)', value=['l2'])
	solver = gr.Dropdown(['lbfgs','liblinear','saga','sag','newton-cg'], value='lbfgs', label='Solver')
	max_iter = gr.Slider(50,1000,value=200,step=10,label='Max iterations')
	cv_folds = gr.Slider(2,10,value=5,step=1,label='CV folds for GridSearch')
	n_jobs = gr.Slider(1,8,value=1,step=1,label='n_jobs for GridSearch')

	train_btn = gr.Button("Train model")

	with gr.Row():
	with gr.Column():
	accuracy_text = gr.Textbox(label='Accuracy & notes', interactive=False)
	conf_plot = gr.Plot(label='Confusion Matrix')
	with gr.Column():
	class_report = gr.Textbox(label='Classification report', interactive=False)
	model_obj = gr.JSON(label='Trained model (sklearn pipeline as repr)')

	# State to keep dataframe
	df_state = gr.State()

	# Wire upload -> get columns
	file_input.change(fn=on_upload, inputs=[file_input], outputs=[target_dropdown, load_status, df_state])

	def preview(df):
	if df is None:
	return pd.DataFrame()
	return df.head(20)

	preview_button.click(fn=preview, inputs=[df_state], outputs=[preview_output])

	def do_train(df, target, test_size_val, rand_state, impute_s, scale_flag, encode_flag,
	use_grid_flag, cmin, cmax, csteps, penalties_sel, solver_sel, cv_f, max_it, n_jobs_val):
	msg, fig, report, model = train_model(df, target, test_size_val, int(rand_state), impute_s, scale_flag, encode_flag,
	use_grid_flag, float(cmin), float(cmax), int(csteps), penalties_sel, solver_sel, int(cv_f), int(max_it), int(n_jobs_val))
	model_repr = str(model)
	return msg, fig, report, model_repr

	train_btn.click(fn=do_train, inputs=[df_state, target_dropdown, test_size, random_state, impute_radio, scaler_checkbox, encode_checkbox,
	use_grid, c_min, c_max, c_steps, penalties, solver, cv_folds, max_iter, n_jobs],
	outputs=[accuracy_text, conf_plot, class_report, model_obj])


	if __name__ == '__main__':
	demo.launch(server_name='0.0.0.0', share=False)