def train(args, exp_num): args_subset = ['exp', 'cpk', 'model', 'time'] book = BookKeeper(args, args_subset, args_dict_update={}, tensorboard=args.tb) args = book.args global ARGS ARGS = args ## Start Log book._start_log() ## Training parameters path2data = args.path2data dataset = args.dataset lmksSubset = args.lmksSubset desc = args.desc split = (args.train_frac, args.dev_frac) idx_dependent = args.idx_dependent batch_size = args.batch_size time = args.time chunks = args.chunks offset = args.offset mask = args.mask feats_kind = args.feats_kind s2v = args.s2v f_new = args.f_new curriculum = args.curriculum kl_anneal = args.kl_anneal ## Load data iterables data = Data(path2data, dataset, lmksSubset, desc, split, batch_size=batch_size, time=time, chunks=chunks, offset=offset, shuffle=True, mask=mask, feats_kind=feats_kind, s2v=s2v, f_new=f_new) print('Data Loaded') ## Create a model device = torch.device('cuda:{}'.format(args.cuda)) if args.cuda>=0 else torch.device('cpu') input_shape = data.input_shape kwargs_keys = ['pose_size', 'trajectory_size'] modelKwargs = {key:input_shape[key] for key in kwargs_keys} modelKwargs.update(args.modelKwargs) model = eval(args.model)(**modelKwargs) model.to(device).double() book._copy_best_model(model) print('Model Created') ## Load model if args.load: print('Loading Model') book._load_model(model) ## Loss function criterion = Loss(args.losses, args.lossKwargs) ## Optimizers optim = torch.optim.Adam(model.parameters(), lr=args.lr) #optim = torch.optim.RMSprop(model.parameters(), lr=args.lr) ## LR scheduler scheduler = lr_scheduler.ExponentialLR(optim, gamma=0.99) ## Transforms columns = get_columns(feats_kind, data) pre = Transforms(args.transforms, columns, args.seed, mask, feats_kind, dataset, f_new) def loop(model, data, pre, desc='train', epoch=0): running_loss = 0 running_internal_loss = 0 running_count = 0 # if kl_anneal > 0: # kl_weight = lambda x: min((x+1)/(kl_anneal+1.), 2) # else: # kl_weight = lambda x: 1 count = 0 if desc == 'train': model.train(True) else: model.eval() Tqdm = tqdm(data, desc=desc+' {:.4f}'.format(running_loss/(count+1.)), leave=False, ncols=20) for count, batch in enumerate(Tqdm): model.zero_grad() optim.zero_grad() X, Y = batch['input'], batch['output'] pose, trajectory, start_trajectory = X pose_gt, trajectory_gt, start_trajectory_gt = Y x = torch.cat((trajectory, pose), dim=-1) y = torch.cat((trajectory_gt, pose_gt), dim=-1) x = x.to(device) y = y.to(device) ## Transform before the model x = pre.transform(x) y = pre.transform(y) if desc=='train': y_cap, internal_losses = model(x, train=True) else: y_cap, internal_losses = model(x, train=False) loss = 0 loss_ = 0 if y_cap is not None: ## if model returns only internal losses loss = criterion(y_cap, y) loss_ = loss.item() for i_loss in internal_losses: loss += i_loss loss_ += i_loss.item() running_internal_loss += i_loss.item() running_count += np.prod(y.shape) running_loss += loss_ # loss = criterion(y_cap, y) # loss_= loss.item() # #if count == 0 and desc == 'train': # # pdb.set_trace() # for i_loss in internal_losses: # loss += kl_weight(epoch) * i_loss # loss_ += i_loss.item() # running_internal_loss += i_loss # #running_loss += loss.item() # running_loss += loss_ ## update tqdm Tqdm.set_description(desc+' {:.4f} {:.4f}'.format(running_loss/running_count, running_internal_loss/running_count)) Tqdm.refresh() if desc == 'train': loss.backward() optim.step() # if kl_anneal == 0: # y_cap, internal_losses = model(x, train=True, epoch=epoch) # sum(internal_losses).backward() # optim.step() x = x.detach() y = y.detach() loss = loss.detach() if y_cap is not None: y_cap = y_cap.detach() internal_losses = [i.detach() for i in internal_losses] if count>=0 and args.debug: ## debugging by overfitting break return running_loss/running_count num_epochs = args.num_epochs ## set up curriculum learning for training time_list = [] time_list_idx = 0 if curriculum: for power in range(1, int(np.log2(time-1)) + 1): time_list.append(2**power) data.update_dataloaders(time_list[0]) time_list.append(time) ## Training Loop for epoch in tqdm(range(num_epochs), ncols=20): train_loss = loop(model, data.train, pre, 'train', epoch) dev_loss = loop(model, data.dev, pre, 'dev') test_loss = loop(model, data.test, pre, 'test') scheduler.step() ## Change the Learning Rate ## save results book.update_res({'train':train_loss, 'dev':dev_loss, 'test':test_loss}) book._save_res() ## update tensorboard book.update_tb({'scalar':[[f'{args.cpk}/train', train_loss, epoch], [f'{args.cpk}/dev', dev_loss, epoch], [f'{args.cpk}/test', test_loss, epoch]]}) # 'histogram':[[f'{args.cpk}/'+name, param.clone().cpu().detach().numpy(), epoch] # for name, param in model.named_parameters()]}) ## print results book.print_res(epoch, key_order=['train','dev','test'], exp=exp_num, lr=scheduler.get_lr()) ## ignore increasing dev loss till the annealing occurs # if epoch < kl_anneal: # book.stop_count = 0 if book.stop_training(model, epoch): ## if early_stopping criterion is met, ## start training with more time steps time_list_idx += 1 book.stop_count = 0 ## reset the threshold counter book.best_dev_score = np.inf model.load_state_dict(copy.deepcopy(book.best_model)) if len(time_list) > time_list_idx: time_ = time_list[time_list_idx] data.update_dataloaders(time_) tqdm.write('Training up to time: {}'.format(time_)) else: break # End Log book._stop_log() # ## Sample print('Loading the best model and training with language input as well') args.__dict__.update({'load':book.name(book.weights_ext[0], book.weights_ext[1], args.save_dir), 'model':'Seq2SeqConditioned10'}) train_wordConditioned(args, exp_num, data)
def train(args, exp_num, data=None): #assert args.load, 'Model name not provided' #assert os.path.isfile(args.load), 'Model file not found' if args.load and os.path.isfile(args.load): load_pretrained_model = True else: load_pretrained_model = False args_subset = ['exp', 'cpk', 'model', 'time', 'chunks'] book = BookKeeper(args, args_subset, args_dict_update={ 'chunks': args.chunks, 'batch_size': args.batch_size, 'model': args.model, 's2v': args.s2v, 'cuda': args.cuda, 'save_dir': args.save_dir, 'early_stopping': args.early_stopping, 'debug': args.debug, 'stop_thresh': args.stop_thresh, 'desc': args.desc, 'curriculum': args.curriculum, 'lr': args.lr }, tensorboard=args.tb, load_pretrained_model=load_pretrained_model) ## load_pretrained_model makes sure that the model is loaded, old save files are not updated and _new_exp is called to assign new filename args = book.args ## Start Log book._start_log() ## Training parameters path2data = args.path2data dataset = args.dataset lmksSubset = args.lmksSubset desc = args.desc split = (args.train_frac, args.dev_frac) idx_dependent = args.idx_dependent batch_size = args.batch_size time = args.time global chunks chunks = args.chunks offset = args.offset mask = args.mask feats_kind = args.feats_kind s2v = args.s2v f_new = args.f_new curriculum = args.curriculum if args.debug: shuffle = False else: shuffle = True ## Load data iterables if data is None: data = Data(path2data, dataset, lmksSubset, desc, split, batch_size=batch_size, time=time, chunks=chunks, offset=offset, shuffle=shuffle, mask=mask, feats_kind=feats_kind, s2v=s2v, f_new=f_new) print('Data Loaded') else: print('Data already loaded! Yesss!!') train = data.train dev = data.dev test = data.test ## Create a model device = torch.device('cuda:{}'.format( args.cuda)) if args.cuda >= 0 else torch.device('cpu') input_shape = data.input_shape kwargs_keys = ['pose_size', 'trajectory_size'] modelKwargs = {key: input_shape[key] for key in kwargs_keys} modelKwargs.update(args.modelKwargs) ## TODO input_size is hardcoded to the w2v input size. can be extracted from Data if args.s2v: input_size = 300 elif args.desc: input_size = len(args.desc) else: input_size = 0 model = eval(args.model)(chunks, input_size=input_size, Seq2SeqKwargs=modelKwargs, load=args.load) model.to(device).double() book._copy_best_model(model) print('Model Created') ## would have to skip this way of loading model #if args.load: # print('Loading Model') # book._load_model(model) ## Loss function criterion = Loss(args.losses, args.lossKwargs) ## Optimizers optim = torch.optim.Adam(model.parameters(), lr=args.lr) ## LR scheduler scheduler = lr_scheduler.ExponentialLR(optim, gamma=0.99) ## Transforms columns = get_columns(feats_kind, data) pre = Transforms(args.transforms, columns, args.seed, mask, feats_kind, dataset, f_new) def loop(model, data, pre, desc='train', epoch=0): running_loss = 0 running_internal_loss = 0 running_count = 0 if desc == 'train': model.train(True) else: model.eval() Tqdm = tqdm(data, desc=desc + ' {:.4f}'.format(0), leave=False, ncols=20) for count, batch in enumerate(Tqdm): model.zero_grad() optim.zero_grad() X, Y, s2v = batch['input'], batch['output'], batch['desc'] pose, trajectory, start_trajectory = X pose_gt, trajectory_gt, start_trajectory_gt = Y x = torch.cat((trajectory, pose), dim=-1) y = torch.cat((trajectory_gt, pose_gt), dim=-1) x = x.to(device) y = y.to(device) if isinstance(s2v, torch.Tensor): s2v = s2v.to(device) ## Transform before the model x = pre.transform(x) y = pre.transform(y) if desc == 'train': y_cap, internal_losses = model(x, s2v, train=True) else: y_cap, internal_losses = model(x, s2v, train=False) loss = 0 loss_ = 0 if y_cap is not None: ## if model returns only internal losses loss = criterion(y_cap, y) loss_ = loss.item() for i_loss in internal_losses: loss += i_loss loss_ += i_loss.item() running_internal_loss += i_loss.item() running_count += np.prod(y.shape) running_loss += loss_ ## update tqdm Tqdm.set_description(desc + ' {:.4f} {:.4f}'.format( running_loss / running_count, running_internal_loss / running_count)) Tqdm.refresh() if desc == 'train': loss.backward() optim.step() x = x.detach() y = y.detach() loss = loss.detach() if y_cap is not None: y_cap = y_cap.detach() internal_losses = [i.detach() for i in internal_losses] if count >= 0 and args.debug: ## debugging by overfitting break return running_loss / running_count num_epochs = args.num_epochs ## set up curriculum learning for training time_list = [] time_list_idx = 0 if curriculum: for power in range(1, int(np.log2(time - 1)) + 1): time_list.append(2**power) data.update_dataloaders(time_list[0]) time_list.append(time) tqdm.write('Training up to time: {}'.format(time_list[time_list_idx])) ## Training Loop for epoch in tqdm(range(num_epochs), ncols=20): train_loss = loop(model, train, pre, 'train', epoch) dev_loss = loop(model, dev, pre, 'dev', epoch) test_loss = loop(model, test, pre, 'test', epoch) scheduler.step() ## Change the Learning Rate ## save results book.update_res({ 'train': train_loss, 'dev': dev_loss, 'test': test_loss }) book._save_res() ## update tensorboard book.update_tb({ 'scalar': [[f'{args.cpk}/train', train_loss, epoch], [f'{args.cpk}/dev', dev_loss, epoch], [f'{args.cpk}/test', test_loss, epoch]] }) # 'histogram':[[f'{args.cpk}/'+name, param.clone().cpu().detach().numpy(), epoch] # for name, param in model.named_parameters()]}) ## print results book.print_res(epoch, key_order=['train', 'dev', 'test'], exp=exp_num, lr=scheduler.get_lr()) if book.stop_training(model, epoch): ## if early_stopping criterion is met, ## start training with more time steps time_list_idx += 1 book.stop_count = 0 ## reset the threshold counter book.best_dev_score = np.inf model.load_state_dict(copy.deepcopy(book.best_model)) if len(time_list) > time_list_idx: time_ = time_list[time_list_idx] data.update_dataloaders(time_) tqdm.write('Training up to time: {}'.format(time_)) else: break ## Sample print('Loading the best model and running the sample loop') args.__dict__.update({ 'load': book.name(book.weights_ext[0], book.weights_ext[1], args.save_dir) }) sample(args, exp_num, data) ## Render (on a cpu only node) # feats_kind_dict = {'rifke':'fke'} # print('Rendering') # render = Slurm('render', slurm_kwargs={'partition':'cpu_long', 'time':'10-00:00', 'n':10}) # python_cmd = ['source activate torch', # 'python render.py -dataset {} -load {} -feats_kind {} -render_list {}'.format( # args.dataset, # args.load, # feats_kind_dict[args.feats_kind], # args.render_list)] # render.run('\n'.join(python_cmd)) ## Render new sentences print('Rendering New Sentences') render_new_sentences(args, exp_num, data) # End Log book._stop_log()
def train(args, exp_num): args_subset = ['exp', 'cpk'] book = BookKeeper(args, args_subset, args_dict_update={}, tensorboard=args.tb) args = book.args ## Start Log book._start_log() ## Training parameters num_epochs = args.num_epochs ## Load data iterables print('Data Loaded') ## Create a model model = Wavenet(num_channels, kernel_size, num_layers, num_lmks, sample_rate_lmks, samples_per_frame, dilation_limit, mfccFlag=mfccFlag) if args.cuda >= 0: model.cuda(args.cuda) book._copy_best_model(model) print('Model Created') ## Load model if args.load: print('Loading Model') book._load_model(model) ## Loss function criterion = torch.nn.MSELoss() ## Optimizers optim = torch.optim.Adam(model.parameters(), lr=args.lr) def loop(model, data, desc='train', epoch=0): running_loss = 0 running_loss_partial = 0 if desc == 'train': model.train(True) else: model.eval() for count, batch in tqdm(enumerate(data), desc=desc, leave=False, ncols=20): pdb.set_trace() ## Training Loop for epoch in tqdm(range(num_epochs), ncols=20): train_loss = loop(model, train, 'train', epoch) dev_loss = loop(model, dev, 'dev') test_loss = loop(model, test, 'test') ## save results book.update_res({ 'train': train_loss, 'dev': dev_loss, 'test': test_loss }) book._save_res() ## print results book.print_res(epoch, key_order=['train', 'dev', 'test'], exp=exp_num) if book.stop_training(model, epoch): break # End Log book._stop_log()