import gradio as gr import torch import joblib import numpy as np import pandas as pd from transformers import AutoTokenizer, AutoModel # Load IndoBERT tokenizer tokenizer = AutoTokenizer.from_pretrained("indolem/indobert-base-uncased") # Load IndoBERT model model = AutoModel.from_pretrained("indolem/indobert-base-uncased") # Mapping dictionaries for labels priority_score_mapping = {1: "LOW", 2: "MEDIUM", 3: "HIGH"} problem_domain_mapping = {0: "OPERATIONAL", 1: "TECHNICAL"} # Load the trained Random Forest models best_classifier1 = joblib.load('best_classifier1_optimized.pkl') best_classifier2 = joblib.load('best_classifier2_optimized.pkl') markdown_text = ''' ## Label Description ### Priority Score * **Low** label, means that the temporary/corrective solution can solve the problem. A permanent solution will be provided later because the impact on the business can still be handled. * **Medium** label, means that there's a need to determine the time constraint to solve the problem. If it remains too long, it will impact the business side. * **High** label, means that the problem is urgent and must be solved immediately. ### Problem Domain * **Operational** label, means that the scope of the problem is on the business or daily operational. * **Technical** label, means that the scope of the problem is on the technical (technology) side like the mobile/web application. ''' description="Write the feedback about the capsule hotel that you've ever visited or stayed there. The machine learning model will predict the priority score and problem domain of the feedback." # Function to perform predictions def predict(text): # Convert the sentences into input features encoded_inputs = tokenizer(text, padding=True, truncation=True, return_tensors="pt", max_length=128) # Perform word embedding using IndoBERT model with torch.no_grad(): outputs = model(**encoded_inputs) embeddings = outputs.last_hidden_state # Convert the embeddings to numpy array embeddings = embeddings.numpy() embeddings_custom_flat = embeddings.reshape(embeddings.shape[0], -1) # Ensure mean_pooled_embeddings has exactly 768 features num_features_expected = 768 if embeddings_custom_flat.shape[1] < num_features_expected: # If the number of features is less than 768, pad the embeddings pad_width = num_features_expected - embeddings_custom_flat.shape[1] embeddings_custom_flat = np.pad(embeddings_custom_flat, ((0, 0), (0, pad_width)), mode='constant') elif embeddings_custom_flat.shape[1] > num_features_expected: # If the number of features is more than 768, truncate the embeddings embeddings_custom_flat = embeddings_custom_flat[:, :num_features_expected] # Predict the priority_score for the custom input custom_priority_score = best_classifier1.predict(embeddings_custom_flat) # Predict the problem_domain for the custom input custom_problem_domain = best_classifier2.predict(embeddings_custom_flat) # Map numerical labels to human-readable labels mapped_priority_score = priority_score_mapping.get(custom_priority_score[0], "unknown") mapped_problem_domain = problem_domain_mapping.get(custom_problem_domain[0], "unknown") return f"Predicted Priority Score: {mapped_priority_score}, Predicted Problem Domain: {mapped_problem_domain}" # Create a Gradio interface gr.Interface(fn=predict, inputs="text", outputs="text", title="Simple Risk Classifier Demo (Case Study: Capsule Hotel)", description=description, article=markdown_text).launch(debug=True)