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import os
import shutil
from pathlib import Path
from typing import List, Tuple, Union
import numpy
import pandas
from concrete.ml.sklearn import XGBClassifier as ConcreteXGBoostClassifier
# Max Input to be displayed on the HuggingFace space brower using Gradio
# Too large inputs, slow down the server: https://github.com/gradio-app/gradio/issues/1877
INPUT_BROWSER_LIMIT = 635
# Store the server's URL
SERVER_URL = "http://localhost:8000/"
CURRENT_DIR = Path(__file__).parent
DEPLOYMENT_DIR = CURRENT_DIR / "deployment"
KEYS_DIR = DEPLOYMENT_DIR / ".fhe_keys"
CLIENT_DIR = DEPLOYMENT_DIR / "client_dir"
SERVER_DIR = DEPLOYMENT_DIR / "server_dir"
ALL_DIRS = [KEYS_DIR, CLIENT_DIR, SERVER_DIR]
# Columns that define the target
TARGET_COLUMNS = ["prognosis_encoded", "prognosis"]
TRAINING_FILENAME = "./data/Training_preprocessed.csv"
TESTING_FILENAME = "./data/Testing_preprocessed.csv"
# pylint: disable=invalid-name
def pretty_print(inputs):
"""
Prettify and sort the input as a list of string.
Args:
inputs (Any): The inputs to be prettified.
Returns:
List: The prettified and sorted list of inputs.
"""
# Convert to a list if necessary
if not isinstance(inputs, (List, Tuple)):
inputs = list(inputs)
# Flatten the list if required
pretty_list = []
for item in inputs:
if isinstance(item, list):
pretty_list.extend([" ".join(subitem.split("_")).title() for subitem in item])
else:
pretty_list.append(" ".join(item.split("_")).title())
# Sort and prettify the input
pretty_list = sorted(list(set(pretty_list)))
return pretty_list
def clean_directory() -> None:
"""
Clear direcgtories
"""
print("Cleaning...\n")
for target_dir in ALL_DIRS:
if os.path.exists(target_dir) and os.path.isdir(target_dir):
shutil.rmtree(target_dir)
target_dir.mkdir(exist_ok=True, parents=True)
def get_disease_name(encoded_prediction: int, file_name: str = TRAINING_FILENAME) -> str:
"""Return the disease name given its encoded label.
Args:
encoded_prediction (int): The encoded prediction
file_name (str): The data file path
Returns:
str: The according disease name
"""
df = pandas.read_csv(file_name, usecols=TARGET_COLUMNS).drop_duplicates()
disease_name, _ = df[df[TARGET_COLUMNS[0]] == encoded_prediction].values.flatten()
return disease_name
def load_data() -> Union[Tuple[pandas.DataFrame, numpy.ndarray], List]:
"""
Return the data
Args:
None
Return:
The train, testing set and valid symptoms.
"""
# Load data
df_train = pandas.read_csv(TRAINING_FILENAME)
df_test = pandas.read_csv(TESTING_FILENAME)
# Separate the traget from the training / testing set:
# TARGET_COLUMNS[0] -> "prognosis_encoded" -> contains the numeric label of the disease
# TARGET_COLUMNS[1] -> "prognosis" -> contains the name of the disease
y_train = df_train[TARGET_COLUMNS[0]]
X_train = df_train.drop(columns=TARGET_COLUMNS, axis=1, errors="ignore")
y_test = df_test[TARGET_COLUMNS[0]]
X_test = df_test.drop(columns=TARGET_COLUMNS, axis=1, errors="ignore")
return (X_train, X_test), (y_train, y_test), X_train.columns.to_list()
def load_model(X_train: pandas.DataFrame, y_train: numpy.ndarray):
"""
Load a pre-trained serialized model
Args:
X_train (pandas.DataFrame): Training set
y_train (numpy.ndarray): Targets of the training set
Return:
The Concrete ML model and its circuit
"""
# Parameters
concrete_args = {"max_depth": 1, "n_bits": 3, "n_estimators": 3, "n_jobs": -1}
classifier = ConcreteXGBoostClassifier(**concrete_args)
# Train the model
classifier.fit(X_train, y_train)
# Compile the model
circuit = classifier.compile(X_train)
return classifier, circuit
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