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Upload server2.py
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- server2.py +42 -55
server2.py
CHANGED
@@ -3,6 +3,8 @@ import pandas as pd
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import seaborn as sns
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import matplotlib.pyplot as plt
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import joblib
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import os
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import shutil
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@@ -20,6 +22,7 @@ else:
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data=pd.read_csv('data/heart.xls')
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data.info() #checking the info
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data_corr=data.corr()
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@@ -27,7 +30,41 @@ data_corr=data.corr()
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plt.figure(figsize=(20,20))
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sns.heatmap(data=data_corr,annot=True)
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#Heatmap for data
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feature_value=np.array(data_corr['output'])
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for i in range(len(feature_value)):
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if feature_value[i]<0:
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@@ -45,9 +82,6 @@ feature_selected #selected features which are very much correalated
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clean_data=data[feature_selected]
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from sklearn.tree import DecisionTreeClassifier #using sklearn decisiontreeclassifier
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from sklearn.model_selection import train_test_split
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#making input and output dataset
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X=clean_data.iloc[:,1:]
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Y=clean_data['output']
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@@ -63,7 +97,7 @@ x_train=sc.fit_transform(x_train)
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x_test=sc.transform(x_test)
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#training our model
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dt=
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dt.fit(x_train,y_train)
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#dt.compile(x_trqin)
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@@ -79,9 +113,10 @@ print("\nThe accuracy of decisiontreelassifier on Heart disease prediction datas
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joblib.dump(dt, 'heart_disease_dt_model.pkl')
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from concrete.ml.sklearn
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fhe_compatible =
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fhe_compatible.compile(x_train)
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@@ -99,51 +134,3 @@ dev.save()
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# Setup the server
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server = FHEModelServer(path_dir=fhe_directory)
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server.load()
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####### client
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from concrete.ml.deployment import FHEModelDev, FHEModelClient, FHEModelServer
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# Setup the client
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client = FHEModelClient(path_dir=fhe_directory, key_dir="/tmp/keys_client")
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serialized_evaluation_keys = client.get_serialized_evaluation_keys()
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# Load the dataset and select the relevant features
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data = pd.read_csv('data/heart.xls')
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# Perform the correlation analysis
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data_corr = data.corr()
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# Select features based on correlation with 'output'
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feature_value = np.array(data_corr['output'])
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for i in range(len(feature_value)):
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if feature_value[i] < 0:
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feature_value[i] = -feature_value[i]
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features_corr = pd.DataFrame(feature_value, index=data_corr['output'].index, columns=['correlation'])
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feature_sorted = features_corr.sort_values(by=['correlation'], ascending=False)
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feature_selected = feature_sorted.index
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# Clean the data by selecting the most correlated features
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clean_data = data[feature_selected]
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# Extract the first row of feature data for prediction (excluding 'output' column)
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sample_data = clean_data.iloc[0, 1:].values.reshape(1, -1) # Reshape to 2D array for model input
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encrypted_data = client.quantize_encrypt_serialize(sample_data)
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##### end client
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encrypted_result = server.run(encrypted_data, serialized_evaluation_keys)
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result = client.deserialize_decrypt_dequantize(encrypted_result)
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print(result)
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import seaborn as sns
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import matplotlib.pyplot as plt
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import joblib
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from sklearn.tree import DecisionTreeClassifier, XGBClassifier #using sklearn decisiontreeclassifier
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from sklearn.model_selection import train_test_split
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import os
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import shutil
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data=pd.read_csv('data/heart.xls')
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data.info() #checking the info
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data_corr=data.corr()
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plt.figure(figsize=(20,20))
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sns.heatmap(data=data_corr,annot=True)
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#Heatmap for data
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"""
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# Get the Data
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X_train, y_train, X_val, y_val = train_test_split()
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classifier = XGBClassifier()
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# Training the Model
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classifier = classifier.fit(X_train, y_train)
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# Trained Model Evaluation on Validation Dataset
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confidence = classifier.score(X_val, y_val)
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# Validation Data Prediction
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y_pred = classifier.predict(X_val)
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# Model Validation Accuracy
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accuracy = accuracy_score(y_val, y_pred)
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# Model Confusion Matrix
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conf_mat = confusion_matrix(y_val, y_pred)
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# Model Classification Report
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clf_report = classification_report(y_val, y_pred)
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# Model Cross Validation Score
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score = cross_val_score(classifier, X_val, y_val, cv=3)
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try:
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# Load Trained Model
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clf = load(str(self.model_save_path + saved_model_name + ".joblib"))
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except Exception as e:
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print("Model not found...")
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if test_data is not None:
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result = clf.predict(test_data)
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print(result)
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else:
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result = clf.predict(self.test_features)
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accuracy = accuracy_score(self.test_labels, result)
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clf_report = classification_report(self.test_labels, result)
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print(accuracy, clf_report)
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"""
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####################
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feature_value=np.array(data_corr['output'])
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for i in range(len(feature_value)):
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if feature_value[i]<0:
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clean_data=data[feature_selected]
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#making input and output dataset
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X=clean_data.iloc[:,1:]
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Y=clean_data['output']
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x_test=sc.transform(x_test)
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#training our model
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dt=XGBClassifier(criterion='entropy',max_depth=6)
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dt.fit(x_train,y_train)
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#dt.compile(x_trqin)
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joblib.dump(dt, 'heart_disease_dt_model.pkl')
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from concrete.ml.sklearn import DecisionTreeClassifier as ConcreteDecisionTreeClassifier
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from concrete.ml.sklearn import XGBClassifier as ConcreteXGBClassifier
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fhe_compatible = ConcreteXGBClassifier.from_sklearn_model(dt, x_train, n_bits = 10) #de FHE
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fhe_compatible.compile(x_train)
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# Setup the server
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server = FHEModelServer(path_dir=fhe_directory)
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server.load()
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