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main.py
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main.py
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import os
import time
import copy
import argparse
import numpy as np
import torch
import torch.nn as nn
from torchvision.utils import save_image
from utils.dc_utils import get_loops, get_dataset, get_network, get_eval_pool, evaluate_synset, get_daparam, match_loss, get_time, TensorDataset, epoch, DiffAugment, ParamDiffAug
def main():
parser = argparse.ArgumentParser(description='Parameter Processing')
parser.add_argument('--method', type=str, default='DC', help='DC/DSA')
parser.add_argument('--dataset', type=str, default='CIFAR10', help='dataset')
parser.add_argument('--model', type=str, default='ConvNet', help='model')
parser.add_argument('--ipc', type=int, default=1, help='image(s) per class')
parser.add_argument('--eval_mode', type=str, default='S', help='eval_mode') # S: the same to training model, M: multi architectures, W: net width, D: net depth, A: activation function, P: pooling layer, N: normalization layer,
parser.add_argument('--num_exp', type=int, default=5, help='the number of experiments')
parser.add_argument('--num_eval', type=int, default=20, help='the number of evaluating randomly initialized models')
parser.add_argument('--epoch_eval_train', type=int, default=300, help='epochs to train a model with synthetic data')
parser.add_argument('--Iteration', type=int, default=1000, help='training iterations')
parser.add_argument('--lr_img', type=float, default=0.1, help='learning rate for updating synthetic images')
parser.add_argument('--lr_net', type=float, default=0.01, help='learning rate for updating network parameters')
parser.add_argument('--batch_real', type=int, default=256, help='batch size for real data')
parser.add_argument('--batch_train', type=int, default=256, help='batch size for training networks')
parser.add_argument('--init', type=str, default='noise', help='noise/real: initialize synthetic images from random noise or randomly sampled real images.')
parser.add_argument('--dsa_strategy', type=str, default='None', help='differentiable Siamese augmentation strategy')
parser.add_argument('--data_path', type=str, default='/data4/sjma/dataset/CIFAR/', help='dataset path')
parser.add_argument('--save_path', type=str, default='result', help='path to save results')
parser.add_argument('--dis_metric', type=str, default='ours', help='distance metric')
parser.add_argument('--is-parallel', action='store_true', default=False, help='use torch data parallel')
parser.add_argument('--seed', type=int, default=1, help='random seed for numpy')
args = parser.parse_args()
args.outer_loop, args.inner_loop = get_loops(args.ipc)
args.device = 'cuda' if torch.cuda.is_available() else 'cpu'
args.dsa_param = ParamDiffAug()
args.dsa = True if args.method == 'DSA' else False
torch.manual_seed(args.seed)
torch.cuda.manual_seed_all(args.seed)
eval_it_pool = np.arange(0, args.Iteration + 1, 500).tolist() if args.eval_mode == 'S' or args.eval_mode == 'SS' else [args.Iteration] # The list of iterations when we evaluate models and record results.
print('eval_it_pool: ', eval_it_pool)
channel, im_size, num_classes, class_names, mean, std, dst_train, dst_test, testloader = get_dataset(args.dataset, args.data_path)
model_eval_pool = get_eval_pool(args.eval_mode, args.model, args.model)
accs_all_exps = dict() # record performances of all experiments
for key in model_eval_pool:
accs_all_exps[key] = []
data_save = []
print('Hyper-parameters: \n', args.__dict__)
print('Evaluation model pool: ', model_eval_pool)
'''save results setting'''
TIME_NOW = str(time.strftime("%Y%m%d-%H%M%S", time.localtime()))
SAVE_PATH = os.path.join(args.save_path, args.method, args.dataset, args.model, str(args.ipc), TIME_NOW)
if not os.path.exists(SAVE_PATH):
os.makedirs(SAVE_PATH)
log_save_path = os.path.join(SAVE_PATH, 'logs.txt')
# save args.txt
args_save_path = os.path.join(SAVE_PATH, 'args.txt')
f_args = open(args_save_path, 'w')
f_args.write('args: \n')
f_args.write(str(vars(args)))
f_args.write('\n')
f_args.write('Hyper-parameters: \n')
f_args.write(str(args.__dict__))
f_args.write('\n\n\n')
f_args.write('Evaluation iteration pool: ')
f_args.write(str(eval_it_pool))
f_args.write('\n\n\n')
f_args.write('Evaluation model pool: ')
f_args.write(str(model_eval_pool))
f_args.close()
for exp in range(args.num_exp):
print('================== Exp %d ==================' % exp)
with open(log_save_path, 'a+') as f_log:
f_log.write('================== Exp %d ==================' % exp)
f_log.write('\n')
''' organize the real dataset '''
images_all = []
labels_all = []
indices_class = [[] for c in range(num_classes)]
images_all = [torch.unsqueeze(dst_train[i][0], dim=0) for i in range(len(dst_train))]
labels_all = [dst_train[i][1] for i in range(len(dst_train))]
for i, lab in enumerate(labels_all):
indices_class[lab].append(i)
images_all = torch.cat(images_all, dim=0).to(args.device)
labels_all = torch.tensor(labels_all, dtype=torch.long, device=args.device)
for c in range(num_classes):
print('class c = %d: %d real images' % (c, len(indices_class[c])))
def get_images(c, n): # get random n images from class c
idx_shuffle = np.random.permutation(indices_class[c])[:n]
return images_all[idx_shuffle]
for ch in range(channel):
print('real images channel %d, mean = %.4f, std = %.4f' % (ch, torch.mean(images_all[:, ch]), torch.std(images_all[:, ch])))
''' initialize the synthetic data '''
image_syn = torch.randn(size=(num_classes * args.ipc, channel, im_size[0], im_size[1]), dtype=torch.float, requires_grad=True, device=args.device)
label_syn = torch.tensor([np.ones(args.ipc, dtype=np.int64) * i for i in range(num_classes)], dtype=torch.long, requires_grad=False, device=args.device).view(-1) # [0,0,0, 1,1,1, ..., 9,9,9]
if args.init == 'real':
print('initialize synthetic data from random real images')
for c in range(num_classes):
image_syn.data[c * args.ipc:(c + 1) * args.ipc] = get_images(c, args.ipc).detach().data
else:
print('initialize synthetic data from random noise')
''' training '''
optimizer_img = torch.optim.SGD([image_syn, ], lr=args.lr_img, momentum=0.5) # optimizer_img for synthetic data
optimizer_img.zero_grad()
criterion = nn.CrossEntropyLoss().to(args.device)
print('%s training begins' % get_time())
with open(log_save_path, 'a+') as f_log:
f_log.write('%s training begins' % get_time())
f_log.write('\n')
for it in range(args.Iteration + 1):
''' Evaluate synthetic data '''
if it in eval_it_pool:
for model_eval in model_eval_pool:
print('-------------------------\nEvaluation\nmodel_train = %s, model_eval = %s, iteration = %d' % (args.model, model_eval, it))
with open(log_save_path, 'a+') as f_log:
f_log.write('-------------------------\nEvaluation\nmodel_train = %s, model_eval = %s, iteration = %d' % (args.model, model_eval, it))
f_log.write('\n')
if args.dsa:
args.epoch_eval_train = 1000
args.dc_aug_param = None
print('DSA augmentation strategy: \n', args.dsa_strategy)
print('DSA augmentation parameters: \n', args.dsa_param.__dict__)
with open(log_save_path, 'a+') as f_log:
f_log.write('DSA augmentation strategy: \n')
f_log.write(args.dsa_strategy)
f_log.write('\n')
f_log.write('DSA augmentation parameters: \n')
f_log.write(str(args.dsa_param.__dict__))
f_log.write('\n')
else:
args.dc_aug_param = get_daparam(args.dataset, args.model, model_eval, args.ipc) # This augmentation parameter set is only for DC method. It will be muted when args.dsa is True.
print('DC augmentation parameters: \n', args.dc_aug_param)
with open(log_save_path, 'a+') as f_log:
f_log.write('DC augmentation parameters: \n')
f_log.write(str(args.dc_aug_param))
f_log.write('\n')
if args.dsa or args.dc_aug_param['strategy'] != 'none':
args.epoch_eval_train = 1000 # Training with data augmentation needs more epochs.
else:
args.epoch_eval_train = 300
accs = []
for it_eval in range(args.num_eval):
net_eval = get_network(model_eval, channel, num_classes, im_size).to(args.device) # get a random model
if args.is_parallel:
net_eval = nn.DataParallel(net_eval)
image_syn_eval, label_syn_eval = copy.deepcopy(image_syn.detach()), copy.deepcopy(label_syn.detach()) # avoid any unaware modification
_, acc_train, acc_test = evaluate_synset(it_eval, net_eval, image_syn_eval, label_syn_eval, testloader, args)
accs.append(acc_test)
print('Evaluate %d random %s, mean = %.4f std = %.4f\n-------------------------' % (len(accs), model_eval, np.mean(accs), np.std(accs)))
with open(log_save_path, 'a+') as f_log:
f_log.write('Evaluate %d random %s, mean = %.4f std = %.4f\n-------------------------' % (len(accs), model_eval, np.mean(accs), np.std(accs)))
f_log.write('\n')
if it == args.Iteration: # record the final results
accs_all_exps[model_eval] += accs
''' visualize and save '''
save_name = os.path.join(SAVE_PATH, 'vis_%s_%s_%s_%dipc_exp%d_iter%d.png' % (args.method, args.dataset, args.model, args.ipc, exp, it))
image_syn_vis = copy.deepcopy(image_syn.detach().cpu())
for ch in range(channel):
image_syn_vis[:, ch] = image_syn_vis[:, ch] * std[ch] + mean[ch]
image_syn_vis[image_syn_vis < 0] = 0.0
image_syn_vis[image_syn_vis > 1] = 1.0
save_image(image_syn_vis, save_name, nrow=args.ipc) # Trying normalize = True/False may get better visual effects.
''' Train synthetic data '''
net = get_network(args.model, channel, num_classes, im_size).to(args.device) # get a random model
if args.is_parallel:
net = nn.DataParallel(net)
net.train()
net_parameters = list(net.parameters())
optimizer_net = torch.optim.SGD(net.parameters(), lr=args.lr_net) # optimizer_img for synthetic data
optimizer_net.zero_grad()
loss_avg = 0
args.dc_aug_param = None # Mute the DC augmentation when learning synthetic data (in inner-loop epoch function) in oder to be consistent with DC paper.
for ol in range(args.outer_loop):
''' freeze the running mu and sigma for BatchNorm layers '''
# Synthetic data batch, e.g. only 1 image/batch, is too small to obtain stable mu and sigma.
# So, we calculate and freeze mu and sigma for BatchNorm layer with real data batch ahead.
# This would make the training with BatchNorm layers easier.
BN_flag = False
BNSizePC = 16 # for batch normalization
for module in net.modules():
if 'BatchNorm' in module._get_name(): #BatchNorm
BN_flag = True
if BN_flag:
img_real = torch.cat([get_images(c, BNSizePC) for c in range(num_classes)], dim=0)
net.train() # for updating the mu, sigma of BatchNorm
output_real = net(img_real) # get running mu, sigma
for module in net.modules():
if 'BatchNorm' in module._get_name(): #BatchNorm
module.eval() # fix mu and sigma of every BatchNorm layer
''' update synthetic data '''
loss = torch.tensor(0.0).to(args.device)
for c in range(num_classes):
img_real = get_images(c, args.batch_real)
lab_real = torch.ones((img_real.shape[0],), device=args.device, dtype=torch.long) * c
img_syn = image_syn[c * args.ipc: (c + 1) * args.ipc].reshape((args.ipc, channel, im_size[0], im_size[1]))
lab_syn = torch.ones((args.ipc,), device=args.device, dtype=torch.long) * c
if args.dsa:
seed = int(time.time() * 1000) % 100000
img_real = DiffAugment(img_real, args.dsa_strategy, seed=seed, param=args.dsa_param)
img_syn = DiffAugment(img_syn, args.dsa_strategy, seed=seed, param=args.dsa_param)
output_real = net(img_real)
loss_real = criterion(output_real, lab_real)
gw_real = torch.autograd.grad(loss_real, net_parameters)
gw_real = list((_.detach().clone() for _ in gw_real))
output_syn = net(img_syn)
loss_syn = criterion(output_syn, lab_syn)
gw_syn = torch.autograd.grad(loss_syn, net_parameters, create_graph=True)
loss += match_loss(gw_syn, gw_real, args)
optimizer_img.zero_grad()
loss.backward()
optimizer_img.step()
loss_avg += loss.item()
if ol == args.outer_loop - 1:
break
''' update network '''
image_syn_train, label_syn_train = copy.deepcopy(image_syn.detach()), copy.deepcopy(label_syn.detach()) # avoid any unaware modification
dst_syn_train = TensorDataset(image_syn_train, label_syn_train)
trainloader = torch.utils.data.DataLoader(dst_syn_train, batch_size=args.batch_train, shuffle=True, num_workers=0)
for il in range(args.inner_loop):
epoch('train', trainloader, net, optimizer_net, criterion, args, aug=True if args.dsa else False)
loss_avg /= (num_classes * args.outer_loop)
if it % 10 == 0:
print('%s iter = %04d, loss = %.4f' % (get_time(), it, loss_avg))
with open(log_save_path, 'a+') as f_log:
f_log.write('%s iter = %04d, loss = %.4f' % (get_time(), it, loss_avg))
f_log.write('\n')
if it == args.Iteration: # only record the final results
data_save.append([copy.deepcopy(image_syn.detach().cpu()), copy.deepcopy(label_syn.detach().cpu())])
torch.save({'data': data_save, 'accs_all_exps': accs_all_exps, }, os.path.join(SAVE_PATH, 'res_%s_%s_%s_%dipc.pt' % (args.method, args.dataset, args.model, args.ipc)))
print('\n==================== Final Results ====================')
with open(log_save_path, 'a+') as f_log:
f_log.write('\n==================== Final Results ====================')
f_log.write('\n')
for key in model_eval_pool:
accs = accs_all_exps[key]
print('Run %d experiments, train on %s, evaluate %d random %s, mean = %.2f%% std = %.2f%%' % (args.num_exp, args.model, len(accs), key, np.mean(accs) * 100, np.std(accs) * 100))
with open(log_save_path, 'a+') as f_log:
f_log.write('Run %d experiments, train on %s, evaluate %d random %s, mean = %.2f%% std = %.2f%%' % (args.num_exp, args.model, len(accs), key, np.mean(accs) * 100, np.std(accs) * 100))
f_log.write('\n')
if __name__ == '__main__':
main()