def main(): args = cfg.parse_args() torch.manual_seed(args.random_seed) random.seed(args.random_seed) torch.cuda.manual_seed(args.random_seed) assert args.exp_name assert args.load_path.endswith('.pth') assert os.path.exists(args.load_path) args.path_helper = set_log_dir('logs_eval', args.exp_name) logger = create_logger(args.path_helper['log_path'], phase='test') # set tf env _init_inception() inception_path = check_or_download_inception(None) create_inception_graph(inception_path) # import network gen_net = eval('models.' + args.model + '.Generator')(args=args).cuda() # fid stat if args.dataset.lower() == 'cifar10': fid_stat = 'fid_stat/fid_stats_cifar10_train.npz' else: raise NotImplementedError(f'no fid stat for {args.dataset.lower()}') assert os.path.exists(fid_stat) # initial np.random.seed(args.random_seed) fixed_z = torch.cuda.FloatTensor( np.random.normal(0, 1, (25, args.latent_dim))) if args.percent < 0.9: pruning_generate(gen_net, (1 - args.percent)) see_remain_rate(gen_net) # set writer logger.info(f'=> resuming from {args.load_path}') checkpoint_file = args.load_path assert os.path.exists(checkpoint_file) checkpoint = torch.load(checkpoint_file) if 'avg_gen_state_dict' in checkpoint: gen_net.load_state_dict(checkpoint['avg_gen_state_dict']) epoch = checkpoint['epoch'] logger.info(f'=> loaded checkpoint {checkpoint_file} (epoch {epoch})') else: gen_net.load_state_dict(checkpoint) logger.info(f'=> loaded checkpoint {checkpoint_file}') logger.info(args) writer_dict = { 'writer': SummaryWriter(args.path_helper['log_path']), 'valid_global_steps': 0, } inception_score, fid_score = validate(args, fixed_z, fid_stat, gen_net, writer_dict, epoch) logger.info(f'Inception score: {inception_score}, FID score: {fid_score}.') writer_dict['writer'].close()
def main(): args = cfg.parse_args() random.seed(args.random_seed) torch.manual_seed(args.random_seed) torch.cuda.manual_seed(args.random_seed) # set tf env _init_inception() inception_path = check_or_download_inception(None) create_inception_graph(inception_path) # import network orig_dis_net = eval('models.'+args.model+'.Discriminator')(args=args).cuda() # weight init gen_net = eval('models.'+args.model+'.Generator')(args=args) dis_net = eval('models.'+args.model+'.Discriminator')(args=args) # weight init def weights_init(m): if isinstance(m, nn.Conv2d): if args.init_type == 'normal': nn.init.normal_(m.weight.data, 0.0, 0.02) elif args.init_type == 'orth': nn.init.orthogonal_(m.weight.data) elif args.init_type == 'xavier_uniform': nn.init.xavier_uniform(m.weight.data, 1.) else: raise NotImplementedError('{} unknown inital type'.format(args.init_type)) elif isinstance(m, nn.BatchNorm2d): nn.init.normal_(m.weight.data, 1.0, 0.02) nn.init.constant_(m.bias.data, 0.0) gen_net.apply(weights_init) dis_net.apply(weights_init) gen_net = gen_net.cuda() dis_net = dis_net.cuda() avg_gen_net = deepcopy(gen_net) initial_gen_net_weight = torch.load(os.path.join(args.init_path, 'initial_gen_net.pth'), map_location="cpu") initial_dis_net_weight = torch.load(os.path.join(args.init_path, 'initial_dis_net.pth'), map_location="cpu") assert id(initial_gen_net_weight) != id(gen_net.state_dict()) assert id(initial_dis_net_weight) != id(dis_net.state_dict()) # set up data_loader dataset = datasets.ImageDataset(args) train_loader = dataset.train # fid stat if args.dataset.lower() == 'cifar10': fid_stat = 'fid_stat/fid_stats_cifar10_train.npz' else: raise NotImplementedError('no fid stat for %s' % args.dataset.lower()) assert os.path.exists(fid_stat) # epoch number for dis_net args.max_epoch = args.max_epoch * args.n_critic if args.max_iter: args.max_epoch = np.ceil(args.max_iter * args.n_critic / len(train_loader)) # initial np.random.seed(args.random_seed) fixed_z = torch.cuda.FloatTensor(np.random.normal(0, 1, (25, args.latent_dim))) start_epoch = 0 args.path_helper = set_log_dir('logs', args.exp_name + "_{}_imp".format(0.8)) logger = create_logger(args.path_helper['log_path']) #logger.info('=> loaded checkpoint %s (epoch %d)' % (checkpoint_file, start_epoch)) logger.info(args) writer_dict = { 'writer': SummaryWriter(args.path_helper['log_path']), 'train_global_steps': start_epoch * len(train_loader), 'valid_global_steps': start_epoch // args.val_freq, } # load initial weights print('=> resuming from %s' % args.load_path) assert os.path.exists(args.load_path) checkpoint_file = os.path.join(args.load_path, 'Model', 'checkpoint.pth') assert os.path.exists(checkpoint_file) checkpoint = torch.load(checkpoint_file) gen_net.load_state_dict(checkpoint['gen_state_dict']) dis_net.load_state_dict(checkpoint['dis_state_dict']) orig_dis_net.load_state_dict(checkpoint['dis_state_dict']) orig_dis_net.eval() round_ = 0 for ro in range(round_, 10): # Reset optimziers best_fid = 1e4 gen_optimizer = torch.optim.Adam(filter(lambda p: p.requires_grad, gen_net.parameters()), args.g_lr, (args.beta1, args.beta2)) dis_optimizer = torch.optim.Adam(filter(lambda p: p.requires_grad, dis_net.parameters()), args.d_lr, (args.beta1, args.beta2)) gen_scheduler = LinearLrDecay(gen_optimizer, args.g_lr, 0.0, 0, args.max_iter * args.n_critic) dis_scheduler = LinearLrDecay(dis_optimizer, args.d_lr, 0.0, 0, args.max_iter * args.n_critic) # Create dis map total = 0 total_nonzero = 0 for m in dis_net.modules(): if isinstance(m, nn.Conv2d): total += m.weight_orig.data.numel() mask = m.weight_orig.data.abs().clone().gt(0).float().cuda() total_nonzero += torch.sum(mask) conv_weights = torch.zeros(total) index = 0 for m in dis_net.modules(): if isinstance(m, nn.Conv2d): size = m.weight_orig.data.numel() conv_weights[index:(index + size)] = m.weight_orig.data.view(-1).abs().clone() index += size y, i = torch.sort(conv_weights) thre_index = total - total_nonzero + int(total_nonzero * 0.2) thre = y[int(thre_index)] pruned = 0 print('Pruning threshold: {}'.format(thre)) zero_flag = False masks = OrderedDict() for k, m in enumerate(dis_net.modules()): if isinstance(m, nn.Conv2d): weight_copy = m.weight_orig.data.abs().clone() mask = weight_copy.gt(thre).float() masks[k] = mask pruned = pruned + mask.numel() - torch.sum(mask) m.weight_orig.data.mul_(mask) if int(torch.sum(mask)) == 0: zero_flag = True print('layer index: {:d} \t total params: {:d} \t remaining params: {:d}'. format(k, mask.numel(), int(torch.sum(mask)))) print('Total conv params: {}, Pruned conv params: {}, Pruned ratio: {}'.format(total, pruned, pruned / total)) # Load initial weights back if args.finetune_D: dis_net.load_state_dict(checkpoint['dis_state_dict']) else: dis_net.load_state_dict(initial_dis_net_weight) # Apply map for k, m in enumerate(dis_net.modules()): if isinstance(m, nn.Conv2d): m.weight_orig.data.mul_(masks[k]) # Generate gen map pruning_generate(gen_net, 0.2) pruning_generate(avg_gen_net, 0.2) see_remain_rate(gen_net) see_remain_rate_orig(dis_net) # Apply map gen_weight = gen_net.state_dict() gen_orig_weight = rewind_weight(initial_gen_net_weight, gen_weight.keys()) assert id(gen_orig_weight) != id(gen_weight) gen_weight.update(gen_orig_weight) gen_net.load_state_dict(gen_weight) gen_avg_param = copy_params(gen_net) for epoch in tqdm(range(int(start_epoch), int(args.max_epoch)), desc='total progress'): lr_schedulers = (gen_scheduler, dis_scheduler) if args.lr_decay else None see_remain_rate(gen_net) if not args.use_kd_D: train_with_mask(args, gen_net, dis_net, gen_optimizer, dis_optimizer, gen_avg_param, train_loader, epoch, writer_dict, masks, lr_schedulers) else: train_with_mask_kd(args, gen_net, dis_net, orig_dis_net, gen_optimizer, dis_optimizer, gen_avg_param, train_loader, epoch, writer_dict, masks, lr_schedulers) try: if epoch and epoch % args.val_freq == 0 or epoch == int(args.max_epoch)-1: backup_param = copy_params(gen_net) load_params(gen_net, gen_avg_param) inception_score, fid_score = validate(args, fixed_z, fid_stat, gen_net, writer_dict, epoch) logger.info('Inception score: %.4f, FID score: %.4f || @ epoch %d.' % (inception_score, fid_score, epoch)) load_params(gen_net, backup_param) if fid_score < best_fid: best_fid = fid_score is_best = True else: is_best = False else: is_best = False except: is_best = False avg_gen_net.load_state_dict(gen_net.state_dict()) load_params(avg_gen_net, gen_avg_param) save_checkpoint_imp({ 'epoch': epoch + 1, 'model': args.model, 'round': ro, 'gen_state_dict': gen_net.state_dict(), 'dis_state_dict': dis_net.state_dict(), 'avg_gen_state_dict': avg_gen_net.state_dict(), 'gen_optimizer': gen_optimizer.state_dict(), 'dis_optimizer': dis_optimizer.state_dict(), 'best_fid': best_fid, 'path_helper': args.path_helper }, is_best, args.path_helper['ckpt_path'])
def main(): args = cfg.parse_args() random.seed(args.random_seed) torch.manual_seed(args.random_seed) torch.cuda.manual_seed(args.random_seed) # set tf env _init_inception() inception_path = check_or_download_inception(None) create_inception_graph(inception_path) # weight init gen_net = eval('models.' + args.model + '.Generator')(args=args) dis_net = eval('models.' + args.model + '.Discriminator')(args=args) # weight init def weights_init(m): if isinstance(m, nn.Conv2d): if args.init_type == 'normal': nn.init.normal_(m.weight.data, 0.0, 0.02) elif args.init_type == 'orth': nn.init.orthogonal_(m.weight.data) elif args.init_type == 'xavier_uniform': nn.init.xavier_uniform(m.weight.data, 1.) else: raise NotImplementedError('{} unknown inital type'.format( args.init_type)) elif isinstance(m, nn.BatchNorm2d): nn.init.normal_(m.weight.data, 1.0, 0.02) nn.init.constant_(m.bias.data, 0.0) gen_net.apply(weights_init) dis_net.apply(weights_init) gen_net = gen_net.cuda() dis_net = dis_net.cuda() avg_gen_net = deepcopy(gen_net) initial_gen_net_weight = deepcopy(gen_net.state_dict()) initial_dis_net_weight = deepcopy(dis_net.state_dict()) assert id(initial_dis_net_weight) != id(dis_net.state_dict()) assert id(initial_gen_net_weight) != id(gen_net.state_dict()) # set optimizer gen_optimizer = torch.optim.Adam( filter(lambda p: p.requires_grad, gen_net.parameters()), args.g_lr, (args.beta1, args.beta2)) dis_optimizer = torch.optim.Adam( filter(lambda p: p.requires_grad, dis_net.parameters()), args.d_lr, (args.beta1, args.beta2)) gen_scheduler = LinearLrDecay(gen_optimizer, args.g_lr, 0.0, 0, args.max_iter * args.n_critic) dis_scheduler = LinearLrDecay(dis_optimizer, args.d_lr, 0.0, 0, args.max_iter * args.n_critic) # set up data_loader dataset = datasets.ImageDataset(args) train_loader = dataset.train # fid stat if args.dataset.lower() == 'cifar10': fid_stat = 'fid_stat/fid_stats_cifar10_train.npz' elif args.dataset.lower() == 'stl10': fid_stat = 'fid_stat/fid_stats_stl10_train.npz' else: raise NotImplementedError('no fid stat for %s' % args.dataset.lower()) assert os.path.exists(fid_stat) # epoch number for dis_net args.max_epoch = args.max_epoch * args.n_critic if args.max_iter: args.max_epoch = np.ceil(args.max_iter * args.n_critic / len(train_loader)) # initial np.random.seed(args.random_seed) fixed_z = torch.cuda.FloatTensor( np.random.normal(0, 1, (25, args.latent_dim))) start_epoch = 0 best_fid = 1e4 args.path_helper = set_log_dir('logs', args.exp_name + "_{}".format(args.percent)) logger = create_logger(args.path_helper['log_path']) # logger.info('=> loaded checkpoint %s (epoch %d)' % (checkpoint_file, start_epoch)) logger.info(args) writer_dict = { 'writer': SummaryWriter(args.path_helper['log_path']), 'train_global_steps': start_epoch * len(train_loader), 'valid_global_steps': start_epoch // args.val_freq, } print('=> resuming from %s' % args.load_path) assert os.path.exists(args.load_path) checkpoint_file = os.path.join(args.load_path, 'Model', 'checkpoint.pth') assert os.path.exists(checkpoint_file) checkpoint = torch.load(checkpoint_file) gen_net.load_state_dict(checkpoint['gen_state_dict']) torch.manual_seed(args.random_seed) pruning_generate(gen_net, (1 - args.percent), args.pruning_method) torch.manual_seed(args.random_seed) pruning_generate(avg_gen_net, (1 - args.percent), args.pruning_method) see_remain_rate(gen_net) if args.second_seed: dis_net.apply(weights_init) if args.finetune_D: dis_net.load_state_dict(checkpoint['dis_state_dict']) else: dis_net.load_state_dict(initial_dis_net_weight) gen_weight = gen_net.state_dict() gen_orig_weight = rewind_weight(initial_gen_net_weight, gen_weight.keys()) assert id(gen_weight) != id(gen_orig_weight) gen_weight.update(gen_orig_weight) gen_net.load_state_dict(gen_weight) gen_avg_param = copy_params(gen_net) if args.use_kd_D: orig_dis_net = eval('models.' + args.model + '.Discriminator')(args=args).cuda() orig_dis_net.load(checkpoint['dis_state_dict']) orig_dis_net.eval() # train loop for epoch in tqdm(range(int(start_epoch), int(args.max_epoch)), desc='total progress'): lr_schedulers = (gen_scheduler, dis_scheduler) if args.lr_decay else None see_remain_rate(gen_net) if not args.use_kd_D: train(args, gen_net, dis_net, gen_optimizer, dis_optimizer, gen_avg_param, train_loader, epoch, writer_dict, lr_schedulers) else: train_kd(args, gen_net, dis_net, orig_dis_net, gen_optimizer, dis_optimizer, gen_avg_param, train_loader, epoch, writer_dict, lr_schedulers) if epoch and epoch % args.val_freq == 0 or epoch == int( args.max_epoch) - 1: backup_param = copy_params(gen_net) load_params(gen_net, gen_avg_param) inception_score, fid_score = validate(args, fixed_z, fid_stat, gen_net, writer_dict, epoch) logger.info( 'Inception score: %.4f, FID score: %.4f || @ epoch %d.' % (inception_score, fid_score, epoch)) load_params(gen_net, backup_param) if fid_score < best_fid: best_fid = fid_score is_best = True else: is_best = False else: is_best = False avg_gen_net.load_state_dict(gen_net.state_dict()) load_params(avg_gen_net, gen_avg_param) save_checkpoint( { 'epoch': epoch + 1, 'model': args.model, 'gen_state_dict': gen_net.state_dict(), 'dis_state_dict': dis_net.state_dict(), 'avg_gen_state_dict': avg_gen_net.state_dict(), 'gen_optimizer': gen_optimizer.state_dict(), 'dis_optimizer': dis_optimizer.state_dict(), 'best_fid': best_fid, 'path_helper': args.path_helper }, is_best, args.path_helper['ckpt_path'])
import torch import models import cfg import numpy as np from utils.utils import set_log_dir, save_checkpoint, create_logger, pruning_generate, see_remain_rate, rewind_weight, see_remain_rate_orig args = cfg.parse_args() gen_net = eval('models.sngan_cifar10.Generator')(args=args).cuda() pruning_generate(gen_net, 1 - 0.8**10) checkpoint = torch.load(args.resume) print(checkpoint['gen_state_dict'].keys()) gen_net.load_state_dict(checkpoint['gen_state_dict']) see_remain_rate(gen_net) num_kernel = 0 zero_kernel = 0 n_kernel = 0 state_dict = checkpoint['gen_state_dict'] for key in state_dict.keys(): if 'mask' in key: mask = state_dict[key] print(mask.shape) num_kernel = num_kernel + mask.shape[1] for i in range(mask.shape[1]): if np.all(mask[:, i, :, :].cpu().numpy() == 0): zero_kernel = zero_kernel + 1 if np.sum(mask[:, i, :, :].cpu().numpy() == 0) > mask[:, i, :, :].reshape(-1).shape[0] * 0.9: n_kernel = n_kernel + 1 print(zero_kernel) print(n_kernel) print(num_kernel)