skd_theshold_weighted_avg.py

import numpy as np
from tensorflow.keras.models import clone_model, load_model
from tensorflow.keras.callbacks import EarlyStopping
import tensorflow as tf

from data_utils import generate_alignment_data
from Neural_Networks import remove_last_layer

class FedMD():
    def __init__(self, parties, public_dataset, 
                 private_data, total_private_data,  
                 private_test_data, N_alignment,
                 N_rounds, 
                 N_logits_matching_round, logits_matching_batchsize, 
                 N_private_training_round, private_training_batchsize):
        
        self.N_parties = len(parties)
        self.public_dataset = public_dataset
        self.private_data = private_data
        self.private_test_data = private_test_data
        self.N_alignment = N_alignment
        
        self.N_rounds = N_rounds
        self.N_logits_matching_round = N_logits_matching_round
        self.logits_matching_batchsize = logits_matching_batchsize
        self.N_private_training_round = N_private_training_round
        self.private_training_batchsize = private_training_batchsize
        
        self.collaborative_parties = []
        self.init_result = []
        
        # train all models in their own private data
        print("start model initialization: ")
        for i in range(self.N_parties):
            print("model ", i)
            model_A_twin = None
            model_A_twin = clone_model(parties[i]) # load private model
            model_A_twin.set_weights(parties[i].get_weights())
            model_A_twin.compile(optimizer=tf.keras.optimizers.Adam(lr = 1e-3), 
                                 loss = "sparse_categorical_crossentropy",
                                 metrics = ["accuracy"])
            
            print("start full stack training ... ")        
            
            # train private models with private data
            model_A_twin.fit(private_data[i]["X"], private_data[i]["y"],
                             batch_size = 32, epochs = 25, shuffle=True, verbose = 0,
                             validation_data = [private_test_data["X"], private_test_data["y"]],
                             callbacks=[EarlyStopping(monitor='val_accuracy', min_delta=0.001, patience=10)]
                            )
            
            print("full stack training done")
            
            model_A = remove_last_layer(model_A_twin, loss="mean_absolute_error")
            
            self.collaborative_parties.append({"model_logits": model_A, 
                                               "model_classifier": model_A_twin,
                                               "model_weights": model_A_twin.get_weights()})
            
            self.init_result.append({"val_acc": model_A_twin.history.history['val_accuracy'],
                                     "train_acc": model_A_twin.history.history['accuracy'],
                                     "val_loss": model_A_twin.history.history['val_loss'],
                                     "train_loss": model_A_twin.history.history['loss'],
                                    })
            
            print()
            del model_A, model_A_twin
        #END FOR LOOP
        
        # theoratical upper bound - acc if the models were trained with all private data
        print("calculate the theoretical upper bounds for participants: ")
        
        self.upper_bounds = []
        self.pooled_train_result = []
        for model in parties:
            model_ub = clone_model(model)
            model_ub.set_weights(model.get_weights())
            model_ub.compile(optimizer=tf.keras.optimizers.Adam(lr = 1e-3),
                             loss = "sparse_categorical_crossentropy", 
                             metrics = ["accuracy"])
            
            model_ub.fit(total_private_data["X"], total_private_data["y"],
                         batch_size = 32, epochs = 50, shuffle=True, verbose = 0, 
                         validation_data = [private_test_data["X"], private_test_data["y"]],
                         callbacks=[EarlyStopping(monitor="val_accuracy", min_delta=0.001, patience=10)])
            
            self.upper_bounds.append(model_ub.history.history["val_accuracy"][-1])
            self.pooled_train_result.append({"val_acc": model_ub.history.history["val_accuracy"], 
                                             "acc": model_ub.history.history["accuracy"]})
            
            del model_ub    
        print("the upper bounds are:", self.upper_bounds)
    
    
    def collaborative_training(self):
        # start collaborating training    
        collaboration_performance = {i: [] for i in range(self.N_parties)}
        r = 0
        while True:
            # At beginning of each round, generate new alignment dataset
            # subset of MNIST train data of 5000 samples
            alignment_data = generate_alignment_data(self.public_dataset["X"], 
                                                     self.public_dataset["y"],
                                                     self.N_alignment)
            
            print("round ", r)
            
            print("update logits ... ")

            # test performance
            print("test performance ... ")
            
            weights = []
            for index, d in enumerate(self.collaborative_parties):
                y_pred = d["model_classifier"].predict(self.private_test_data["X"], verbose = 0).argmax(axis = 1)
                acc = np.mean(self.private_test_data["y"] == y_pred)
                collaboration_performance[index].append(acc)
                weights.append(acc)
                
                print(collaboration_performance[index][-1])
                del y_pred
            
            total_weight = sum(weights)
            weights = [w/total_weight for w in weights] # normalize the weights so they sum to 1

            # update logits
            logits = 0
            for index, d in enumerate(self.collaborative_parties):
                d["model_logits"].set_weights(d["model_weights"])
                logits += weights[index] * d["model_logits"].predict(alignment_data["X"], verbose = 0)

            r+= 1
            if r > self.N_rounds:
                break
                
                
            print("updates models ...")
            for index, d in enumerate(self.collaborative_parties):
                print("model {0} starting alignment with public logits... ".format(index))
                
                
                weights_to_use = None
                weights_to_use = d["model_weights"]

                d["model_logits"].set_weights(weights_to_use)
                d["model_logits"].fit(alignment_data["X"], logits, 
                                      batch_size = self.logits_matching_batchsize,  
                                      epochs = self.N_logits_matching_round, 
                                      shuffle=True, verbose = 0)
                d["model_weights"] = d["model_logits"].get_weights()
                print("model {0} done alignment".format(index))

                print("model {0} starting training with private data... ".format(index))
                weights_to_use = None
                weights_to_use = d["model_weights"]
                d["model_classifier"].set_weights(weights_to_use)
                d["model_classifier"].fit(self.private_data[index]["X"], 
                                          self.private_data[index]["y"],       
                                          batch_size = self.private_training_batchsize, 
                                          epochs = self.N_private_training_round, 
                                          shuffle=True, verbose = 0)

                d["model_weights"] = d["model_classifier"].get_weights()
                print("model {0} done private training. \n".format(index))
            #END FOR LOOP
        
        #END WHILE LOOP
        return collaboration_performance