bayesiancnn/main_frequentist.py

from __future__ import print_function
import os
import data
import torch
# import pickle
import metrics
import numpy as np
import torch.nn as nn
from datetime import datetime
from torch.optim import Adam, lr_scheduler
from models.NonBayesianModels.LeNet import LeNet
from models.NonBayesianModels.AlexNet import AlexNet
from stopping_crit import earlyStopping, energyBound, accuracyBound
from models.NonBayesianModels.ThreeConvThreeFC import ThreeConvThreeFC

# with (open("configuration.pkl", "rb")) as file:
#     while True:
#         try:
#             cfg = pickle.load(file)
#         except EOFError:
#             break

cfg = {
        "model": {"net_type": "lenet", "type": "freq", "size": 1,
                  "layer_type": "lrt", "activation_type": "softplus",
                  "priors": {
                      'prior_mu': 0,
                      'prior_sigma': 0.1,
                      'posterior_mu_initial': (0, 0.1),  # (mean,std) normal_
                      'posterior_rho_initial': (-5, 0.1),  # (mean,std) normal_
                      },
                  "n_epochs": 100,
                  "sens": 1e-9,
                  "energy_thrs": 100000,
                  "acc_thrs": 0.99,
                  "lr": 0.001,
                  "num_workers": 4,
                  "valid_size": 0.2,
                  "batch_size": 256,
                  "train_ens": 1,
                  "valid_ens": 1,
                  "beta_type": 0.1,  # 'Blundell','Standard',etc.
                  # Use float for const value
                  },
        #"data": "CIFAR10",
        "data": "MNIST",
        "stopping_crit": 1,
        "save": 1,
        "pickle_path": None,
}

# CUDA settings
device = torch.device("cuda:0" if torch.cuda.is_available() else "cpu")


def getModel(net_type, inputs, outputs, wide=cfg["model"]["size"]):
    if (net_type == 'lenet'):
        return LeNet(outputs, inputs, wide)
    elif (net_type == 'alexnet'):
        return AlexNet(outputs, inputs)
    elif (net_type == '3conv3fc'):
        return ThreeConvThreeFC(outputs, inputs)
    else:
        raise ValueError('Network should be either [LeNet / AlexNet / \
                3Conv3FC')


def train_model(net, optimizer, criterion, train_loader):
    train_loss = 0.0
    net.train()
    accs = []
    for datas, target in train_loader:
        data, target = datas.to(device), target.to(device)
        optimizer.zero_grad()
        output = net(data)
        loss = criterion(output, target)
        loss.backward()
        optimizer.step()
        train_loss += loss.item()*data.size(0)
        accs.append(metrics.acc(output.detach(), target))
    return train_loss, np.mean(accs)


def validate_model(net, criterion, valid_loader):
    valid_loss = 0.0
    net.eval()
    accs = []
    for datas, target in valid_loader:
        data, target = datas.to(device), target.to(device)
        output = net(data)
        loss = criterion(output, target)
        valid_loss += loss.item()*data.size(0)
        accs.append(metrics.acc(output.detach(), target))
    return valid_loss, np.mean(accs)


def run(dataset, net_type):

    # Hyper Parameter settings
    n_epochs = cfg["model"]["n_epochs"]
    lr = cfg["model"]["lr"]
    num_workers = cfg["model"]["num_workers"]
    valid_size = cfg["model"]["valid_size"]
    batch_size = cfg["model"]["batch_size"]

    trainset, testset, inputs, outputs = data.getDataset(dataset)
    train_loader, valid_loader, test_loader = data.getDataloader(
        trainset, testset, valid_size, batch_size, num_workers)
    net = getModel(net_type, inputs, outputs).to(device)

    ckpt_dir = f'checkpoints/{dataset}/frequentist'
    ckpt_name = f'checkpoints/{dataset}/frequentist/model_{net_type}_{cfg["model"]["size"]}'

    if not os.path.exists(ckpt_dir):
        os.makedirs(ckpt_dir, exist_ok=True)

    stp = cfg["stopping_crit"]
    sav = cfg["save"]

    criterion = nn.CrossEntropyLoss()
    optimizer = Adam(net.parameters(), lr=lr)
    lr_sched = lr_scheduler.ReduceLROnPlateau(optimizer, patience=6,
                                              verbose=True)
    # valid_loss_min = np.Inf
    # if stp == 2:
    early_stop = []
    train_data = []
    for epoch in range(1, n_epochs+1):

        train_loss, train_acc = train_model(net, optimizer, criterion,
                                            train_loader)
        valid_loss, valid_acc = validate_model(net, criterion, valid_loader)
        lr_sched.step(valid_loss)

        train_loss = train_loss/len(train_loader.dataset)
        valid_loss = valid_loss/len(valid_loader.dataset)

        train_data.append([epoch, train_loss, train_acc, valid_loss,
                           valid_acc])
        print('Epoch: {} \tTraining Loss: {: .4f} \tTraining Accuracy: {: .4f}\
              \tValidation Loss: {: .4f} \tValidation Accuracy: {: .4f}\
              '.format(epoch, train_loss, train_acc, valid_loss, valid_acc))

        if stp == 2:
            # print('Using early stopping')
            if earlyStopping(early_stop, valid_acc, epoch,
                             cfg["model"]["sens"]) == 1:
                break
        elif stp == 3:
            # print('Using energy bound')
            if energyBound(cfg["model"]["energy_thrs"]) == 1:
                break
        elif stp == 4:
            # print('Using accuracy bound')
            if accuracyBound(train_acc,
                             cfg["model"]["acc_thrs"]) == 1:
                break
        else:
            print('Training for {} epochs'.format(cfg["model"]["n_epochs"]))

        if sav == 1:
            # save model when finished
            # if epoch == n_epochs:
            #     torch.save(net.state_dict(), ckpt_name)
            torch.save({
                'epoch': epoch,
                'model_state_dict': net.state_dict(),
                'optimizer_state_dict': optimizer.state_dict(),
                'loss': train_loss,
                }, ckpt_name + '_epoch_{}.pt'.format(epoch))

#    with open("freq_exp_data_"+str(cfg["model"]["size"])+".pkl", 'wb') as f:
#        pickle.dump(train_data, f)


if __name__ == '__main__':
    now = datetime.now()
    current_time = now.strftime("%H:%M:%S")
    print("Initial Time =", current_time)
    print("Using frequentist model of size: {}".format(cfg["model"]["size"]))
    run(cfg["data"], cfg["model"]["net_type"])
    now = datetime.now()
    current_time = now.strftime("%H:%M:%S")
    print("Final Time =", current_time)
Commited code from 2023 2024-05-10 09:59:24 +00:00			`from __future__ import print_function`
			`import os`
			`import data`
			`import torch`
Commited code from 2024 2024-05-10 10:04:28 +00:00			`# import pickle`
Commited code from 2023 2024-05-10 09:59:24 +00:00			`import metrics`
			`import numpy as np`
			`import torch.nn as nn`
			`from datetime import datetime`
			`from torch.optim import Adam, lr_scheduler`
			`from models.NonBayesianModels.LeNet import LeNet`
			`from models.NonBayesianModels.AlexNet import AlexNet`
			`from stopping_crit import earlyStopping, energyBound, accuracyBound`
			`from models.NonBayesianModels.ThreeConvThreeFC import ThreeConvThreeFC`

Commited code from 2024 2024-05-10 10:04:28 +00:00			`# with (open("configuration.pkl", "rb")) as file:`
			`# while True:`
			`# try:`
			`# cfg = pickle.load(file)`
			`# except EOFError:`
			`# break`

			`cfg = {`
			`"model": {"net_type": "lenet", "type": "freq", "size": 1,`
			`"layer_type": "lrt", "activation_type": "softplus",`
			`"priors": {`
			`'prior_mu': 0,`
			`'prior_sigma': 0.1,`
			`'posterior_mu_initial': (0, 0.1), # (mean,std) normal_`
			`'posterior_rho_initial': (-5, 0.1), # (mean,std) normal_`
			`},`
			`"n_epochs": 100,`
			`"sens": 1e-9,`
			`"energy_thrs": 100000,`
			`"acc_thrs": 0.99,`
			`"lr": 0.001,`
			`"num_workers": 4,`
			`"valid_size": 0.2,`
			`"batch_size": 256,`
			`"train_ens": 1,`
			`"valid_ens": 1,`
			`"beta_type": 0.1, # 'Blundell','Standard',etc.`
			`# Use float for const value`
			`},`
			`#"data": "CIFAR10",`
			`"data": "MNIST",`
			`"stopping_crit": 1,`
			`"save": 1,`
			`"pickle_path": None,`
			`}`
Commited code from 2023 2024-05-10 09:59:24 +00:00
			`# CUDA settings`
			`device = torch.device("cuda:0" if torch.cuda.is_available() else "cpu")`


			`def getModel(net_type, inputs, outputs, wide=cfg["model"]["size"]):`
			`if (net_type == 'lenet'):`
			`return LeNet(outputs, inputs, wide)`
			`elif (net_type == 'alexnet'):`
			`return AlexNet(outputs, inputs)`
			`elif (net_type == '3conv3fc'):`
			`return ThreeConvThreeFC(outputs, inputs)`
			`else:`
			`raise ValueError('Network should be either [LeNet / AlexNet / \`
			`3Conv3FC')`


			`def train_model(net, optimizer, criterion, train_loader):`
			`train_loss = 0.0`
			`net.train()`
			`accs = []`
			`for datas, target in train_loader:`
			`data, target = datas.to(device), target.to(device)`
			`optimizer.zero_grad()`
			`output = net(data)`
			`loss = criterion(output, target)`
			`loss.backward()`
			`optimizer.step()`
			`train_loss += loss.item()*data.size(0)`
			`accs.append(metrics.acc(output.detach(), target))`
			`return train_loss, np.mean(accs)`


			`def validate_model(net, criterion, valid_loader):`
			`valid_loss = 0.0`
			`net.eval()`
			`accs = []`
			`for datas, target in valid_loader:`
			`data, target = datas.to(device), target.to(device)`
			`output = net(data)`
			`loss = criterion(output, target)`
			`valid_loss += loss.item()*data.size(0)`
			`accs.append(metrics.acc(output.detach(), target))`
			`return valid_loss, np.mean(accs)`


			`def run(dataset, net_type):`

			`# Hyper Parameter settings`
			`n_epochs = cfg["model"]["n_epochs"]`
			`lr = cfg["model"]["lr"]`
			`num_workers = cfg["model"]["num_workers"]`
			`valid_size = cfg["model"]["valid_size"]`
			`batch_size = cfg["model"]["batch_size"]`

			`trainset, testset, inputs, outputs = data.getDataset(dataset)`
			`train_loader, valid_loader, test_loader = data.getDataloader(`
			`trainset, testset, valid_size, batch_size, num_workers)`
			`net = getModel(net_type, inputs, outputs).to(device)`

			`ckpt_dir = f'checkpoints/{dataset}/frequentist'`
Commited code from 2024 2024-05-10 10:04:28 +00:00			`ckpt_name = f'checkpoints/{dataset}/frequentist/model_{net_type}_{cfg["model"]["size"]}'`
Commited code from 2023 2024-05-10 09:59:24 +00:00
			`if not os.path.exists(ckpt_dir):`
			`os.makedirs(ckpt_dir, exist_ok=True)`

			`stp = cfg["stopping_crit"]`
			`sav = cfg["save"]`

			`criterion = nn.CrossEntropyLoss()`
			`optimizer = Adam(net.parameters(), lr=lr)`
			`lr_sched = lr_scheduler.ReduceLROnPlateau(optimizer, patience=6,`
			`verbose=True)`
			`# valid_loss_min = np.Inf`
			`# if stp == 2:`
			`early_stop = []`
			`train_data = []`
			`for epoch in range(1, n_epochs+1):`

			`train_loss, train_acc = train_model(net, optimizer, criterion,`
			`train_loader)`
			`valid_loss, valid_acc = validate_model(net, criterion, valid_loader)`
			`lr_sched.step(valid_loss)`

			`train_loss = train_loss/len(train_loader.dataset)`
			`valid_loss = valid_loss/len(valid_loader.dataset)`

			`train_data.append([epoch, train_loss, train_acc, valid_loss,`
			`valid_acc])`
			`print('Epoch: {} \tTraining Loss: {: .4f} \tTraining Accuracy: {: .4f}\`
			`\tValidation Loss: {: .4f} \tValidation Accuracy: {: .4f}\`
			`'.format(epoch, train_loss, train_acc, valid_loss, valid_acc))`

			`if stp == 2:`
			`# print('Using early stopping')`
			`if earlyStopping(early_stop, valid_acc, epoch,`
			`cfg["model"]["sens"]) == 1:`
			`break`
			`elif stp == 3:`
			`# print('Using energy bound')`
			`if energyBound(cfg["model"]["energy_thrs"]) == 1:`
			`break`
			`elif stp == 4:`
			`# print('Using accuracy bound')`
			`if accuracyBound(train_acc,`
			`cfg["model"]["acc_thrs"]) == 1:`
			`break`
			`else:`
			`print('Training for {} epochs'.format(cfg["model"]["n_epochs"]))`

			`if sav == 1:`
			`# save model when finished`
Commited code from 2024 2024-05-10 10:04:28 +00:00			`# if epoch == n_epochs:`
			`# torch.save(net.state_dict(), ckpt_name)`
			`torch.save({`
			`'epoch': epoch,`
			`'model_state_dict': net.state_dict(),`
			`'optimizer_state_dict': optimizer.state_dict(),`
			`'loss': train_loss,`
			`}, ckpt_name + '_epoch_{}.pt'.format(epoch))`

			`# with open("freq_exp_data_"+str(cfg["model"]["size"])+".pkl", 'wb') as f:`
			`# pickle.dump(train_data, f)`
Commited code from 2023 2024-05-10 09:59:24 +00:00

			`if __name__ == '__main__':`
			`now = datetime.now()`
			`current_time = now.strftime("%H:%M:%S")`
			`print("Initial Time =", current_time)`
			`print("Using frequentist model of size: {}".format(cfg["model"]["size"]))`
			`run(cfg["data"], cfg["model"]["net_type"])`
			`now = datetime.now()`
			`current_time = now.strftime("%H:%M:%S")`
			`print("Final Time =", current_time)`