def test_main(): parser = argparse.ArgumentParser(description='PyTorch MNIST Example') parser.add_argument('--test-batch-size', type=int, default=1000, metavar='N', help='input batch size for testing (default: 1000)') parser.add_argument('--epochs', type=int, default=10, metavar='N', help='number of epochs to train (default: 10)') parser.add_argument('--lr', type=float, default=0.01, metavar='LR', help='learning rate (default: 0.01)') parser.add_argument('--momentum', type=float, default=0.5, metavar='M', help='SGD momentum (default: 0.5)') parser.add_argument('--no-cuda', action='store_true', default=False, help='disables CUDA training') parser.add_argument('--seed', type=int, default=1, metavar='S', help='random seed (default: 1)') parser.add_argument( '--log-interval', type=int, default=10, metavar='N', help='how many batches to wait before logging training status') parser.add_argument('--save-model', action='store_true', default=False, help='For Saving the current Model') parser.add_argument('--wandb', type=int, default=1, help='log to weights and biases') parser.add_argument('--autograd_check', type=int, default=0, help='autograd correctness checks') parser.add_argument('--logdir', type=str, default='/temp/runs/curv_train_tiny/run') parser.add_argument('--train_batch_size', type=int, default=100) parser.add_argument('--stats_batch_size', type=int, default=60000) parser.add_argument('--dataset_size', type=int, default=60000) parser.add_argument('--train_steps', type=int, default=100, help="this many train steps between stat collection") parser.add_argument('--stats_steps', type=int, default=1000000, help="total number of curvature stats collections") parser.add_argument('--nonlin', type=int, default=1, help="whether to add ReLU nonlinearity between layers") parser.add_argument('--method', type=str, choices=['gradient', 'newton'], default='gradient', help="descent method, newton or gradient") parser.add_argument('--layer', type=int, default=-1, help="restrict updates to this layer") parser.add_argument('--data_width', type=int, default=28) parser.add_argument('--targets_width', type=int, default=28) parser.add_argument('--lmb', type=float, default=1e-3) parser.add_argument( '--hess_samples', type=int, default=1, help='number of samples when sub-sampling outputs, 0 for exact hessian' ) parser.add_argument('--hess_kfac', type=int, default=0, help='whether to use KFAC approximation for hessian') parser.add_argument('--compute_rho', type=int, default=1, help='use expensive method to compute rho') parser.add_argument('--skip_stats', type=int, default=0, help='skip all stats collection') parser.add_argument('--full_batch', type=int, default=0, help='do stats on the whole dataset') parser.add_argument('--weight_decay', type=float, default=1e-4) #args = parser.parse_args() args = AttrDict() args.lmb = 1e-3 args.compute_rho = 1 args.weight_decay = 1e-4 args.method = 'gradient' args.logdir = '/tmp' args.data_width = 2 args.targets_width = 2 args.train_batch_size = 10 args.full_batch = False args.skip_stats = False args.autograd_check = False u.seed_random(1) logdir = u.create_local_logdir(args.logdir) run_name = os.path.basename(logdir) #gl.event_writer = SummaryWriter(logdir) gl.event_writer = u.NoOp() # print(f"Logging to {run_name}") # small values for debugging # loss_type = 'LeastSquares' loss_type = 'CrossEntropy' args.wandb = 0 args.stats_steps = 10 args.train_steps = 10 args.stats_batch_size = 10 args.data_width = 2 args.targets_width = 2 args.nonlin = False d1 = args.data_width**2 d2 = 2 d3 = args.targets_width**2 d1 = args.data_width**2 assert args.data_width == args.targets_width o = d1 n = args.stats_batch_size d = [d1, 30, 30, 30, 20, 30, 30, 30, d1] if loss_type == 'CrossEntropy': d3 = 10 o = d3 n = args.stats_batch_size d = [d1, d2, d3] dsize = max(args.train_batch_size, args.stats_batch_size) + 1 model = u.SimpleFullyConnected2(d, bias=True, nonlin=args.nonlin) model = model.to(gl.device) try: # os.environ['WANDB_SILENT'] = 'true' if args.wandb: wandb.init(project='curv_train_tiny', name=run_name) wandb.tensorboard.patch(tensorboardX=False) wandb.config['train_batch'] = args.train_batch_size wandb.config['stats_batch'] = args.stats_batch_size wandb.config['method'] = args.method wandb.config['n'] = n except Exception as e: print(f"wandb crash with {e}") # optimizer = torch.optim.SGD(model.parameters(), lr=0.03, momentum=0.9) optimizer = torch.optim.Adam( model.parameters(), lr=0.03) # make 10x smaller for least-squares loss dataset = u.TinyMNIST(data_width=args.data_width, targets_width=args.targets_width, dataset_size=dsize, original_targets=True) train_loader = torch.utils.data.DataLoader( dataset, batch_size=args.train_batch_size, shuffle=False, drop_last=True) train_iter = u.infinite_iter(train_loader) stats_iter = None if not args.full_batch: stats_loader = torch.utils.data.DataLoader( dataset, batch_size=args.stats_batch_size, shuffle=False, drop_last=True) stats_iter = u.infinite_iter(stats_loader) test_dataset = u.TinyMNIST(data_width=args.data_width, targets_width=args.targets_width, train=False, dataset_size=dsize, original_targets=True) test_loader = torch.utils.data.DataLoader(test_dataset, batch_size=args.train_batch_size, shuffle=False, drop_last=True) test_iter = u.infinite_iter(test_loader) if loss_type == 'LeastSquares': loss_fn = u.least_squares elif loss_type == 'CrossEntropy': loss_fn = nn.CrossEntropyLoss() autograd_lib.add_hooks(model) gl.token_count = 0 last_outer = 0 val_losses = [] for step in range(args.stats_steps): if last_outer: u.log_scalars( {"time/outer": 1000 * (time.perf_counter() - last_outer)}) last_outer = time.perf_counter() with u.timeit("val_loss"): test_data, test_targets = next(test_iter) test_output = model(test_data) val_loss = loss_fn(test_output, test_targets) # print("val_loss", val_loss.item()) val_losses.append(val_loss.item()) u.log_scalar(val_loss=val_loss.item()) # compute stats if args.full_batch: data, targets = dataset.data, dataset.targets else: data, targets = next(stats_iter) # Capture Hessian and gradient stats autograd_lib.enable_hooks() autograd_lib.clear_backprops(model) autograd_lib.clear_hess_backprops(model) with u.timeit("backprop_g"): output = model(data) loss = loss_fn(output, targets) loss.backward(retain_graph=True) with u.timeit("backprop_H"): autograd_lib.backprop_hess(output, hess_type=loss_type) autograd_lib.disable_hooks() # TODO(y): use remove_hooks with u.timeit("compute_grad1"): autograd_lib.compute_grad1(model) with u.timeit("compute_hess"): autograd_lib.compute_hess(model) for (i, layer) in enumerate(model.layers): # input/output layers are unreasonably expensive if not using Kronecker factoring if d[i] > 50 or d[i + 1] > 50: print( f'layer {i} is too big ({d[i], d[i + 1]}), skipping stats') continue if args.skip_stats: continue s = AttrDefault(str, {}) # dictionary-like object for layer stats ############################# # Gradient stats ############################# A_t = layer.activations assert A_t.shape == (n, d[i]) # add factor of n because backprop takes loss averaged over batch, while we need per-example loss B_t = layer.backprops_list[0] * n assert B_t.shape == (n, d[i + 1]) with u.timeit(f"khatri_g-{i}"): G = u.khatri_rao_t(B_t, A_t) # batch loss Jacobian assert G.shape == (n, d[i] * d[i + 1]) g = G.sum(dim=0, keepdim=True) / n # average gradient assert g.shape == (1, d[i] * d[i + 1]) u.check_equal(G.reshape(layer.weight.grad1.shape), layer.weight.grad1) if args.autograd_check: u.check_close(B_t.t() @ A_t / n, layer.weight.saved_grad) u.check_close(g.reshape(d[i + 1], d[i]), layer.weight.saved_grad) s.sparsity = torch.sum(layer.output <= 0) / layer.output.numel( ) # proportion of activations that are zero s.mean_activation = torch.mean(A_t) s.mean_backprop = torch.mean(B_t) # empirical Fisher with u.timeit(f'sigma-{i}'): efisher = G.t() @ G / n sigma = efisher - g.t() @ g s.sigma_l2 = u.sym_l2_norm(sigma) s.sigma_erank = torch.trace(sigma) / s.sigma_l2 lambda_regularizer = args.lmb * torch.eye(d[i + 1] * d[i]).to( gl.device) H = layer.weight.hess with u.timeit(f"invH-{i}"): invH = torch.cholesky_inverse(H + lambda_regularizer) with u.timeit(f"H_l2-{i}"): s.H_l2 = u.sym_l2_norm(H) s.iH_l2 = u.sym_l2_norm(invH) with u.timeit(f"norms-{i}"): s.H_fro = H.flatten().norm() s.iH_fro = invH.flatten().norm() s.grad_fro = g.flatten().norm() s.param_fro = layer.weight.data.flatten().norm() u.nan_check(H) if args.autograd_check: model.zero_grad() output = model(data) loss = loss_fn(output, targets) H_autograd = u.hessian(loss, layer.weight) H_autograd = H_autograd.reshape(d[i] * d[i + 1], d[i] * d[i + 1]) u.check_close(H, H_autograd) # u.dump(sigma, f'/tmp/sigmas/H-{step}-{i}') def loss_direction(dd: torch.Tensor, eps): """loss improvement if we take step eps in direction dd""" return u.to_python_scalar(eps * (dd @ g.t()) - 0.5 * eps**2 * dd @ H @ dd.t()) def curv_direction(dd: torch.Tensor): """Curvature in direction dd""" return u.to_python_scalar(dd @ H @ dd.t() / (dd.flatten().norm()**2)) with u.timeit(f"pinvH-{i}"): pinvH = H.pinverse() with u.timeit(f'curv-{i}'): s.grad_curv = curv_direction(g) ndir = g @ pinvH # newton direction s.newton_curv = curv_direction(ndir) setattr(layer.weight, 'pre', pinvH) # save Newton preconditioner s.step_openai = s.grad_fro**2 / s.grad_curv if s.grad_curv else 999 s.step_max = 2 / s.H_l2 s.step_min = torch.tensor(2) / torch.trace(H) s.newton_fro = ndir.flatten().norm( ) # frobenius norm of Newton update s.regret_newton = u.to_python_scalar( g @ pinvH @ g.t() / 2) # replace with "quadratic_form" s.regret_gradient = loss_direction(g, s.step_openai) with u.timeit(f'rho-{i}'): p_sigma = u.lyapunov_spectral(H, sigma) discrepancy = torch.max(abs(p_sigma - p_sigma.t()) / p_sigma) s.psigma_erank = u.sym_erank(p_sigma) s.rho = H.shape[0] / s.psigma_erank with u.timeit(f"batch-{i}"): s.batch_openai = torch.trace(H @ sigma) / (g @ H @ g.t()) s.diversity = torch.norm(G, "fro")**2 / torch.norm(g)**2 / n # Faster approaches for noise variance computation # s.noise_variance = torch.trace(H.inverse() @ sigma) # try: # # this fails with singular sigma # s.noise_variance = torch.trace(torch.solve(sigma, H)[0]) # # s.noise_variance = torch.trace(torch.lstsq(sigma, H)[0]) # pass # except RuntimeError as _: s.noise_variance_pinv = torch.trace(pinvH @ sigma) s.H_erank = torch.trace(H) / s.H_l2 s.batch_jain_simple = 1 + s.H_erank s.batch_jain_full = 1 + s.rho * s.H_erank u.log_scalars(u.nest_stats(layer.name, s)) # gradient steps with u.timeit('inner'): for i in range(args.train_steps): optimizer.zero_grad() data, targets = next(train_iter) model.zero_grad() output = model(data) loss = loss_fn(output, targets) loss.backward() # u.log_scalar(train_loss=loss.item()) if args.method != 'newton': optimizer.step() if args.weight_decay: for group in optimizer.param_groups: for param in group['params']: param.data.mul_(1 - args.weight_decay) else: for (layer_idx, layer) in enumerate(model.layers): param: torch.nn.Parameter = layer.weight param_data: torch.Tensor = param.data param_data.copy_(param_data - 0.1 * param.grad) if layer_idx != 1: # only update 1 layer with Newton, unstable otherwise continue u.nan_check(layer.weight.pre) u.nan_check(param.grad.flatten()) u.nan_check( u.v2r(param.grad.flatten()) @ layer.weight.pre) param_new_flat = u.v2r(param_data.flatten()) - u.v2r( param.grad.flatten()) @ layer.weight.pre u.nan_check(param_new_flat) param_data.copy_( param_new_flat.reshape(param_data.shape)) gl.token_count += data.shape[0] gl.event_writer.close() assert val_losses[0] > 2.4 # 2.4828238487243652 assert val_losses[-1] < 2.25 # 2.20609712600708
def main(): u.seed_random(1) logdir = u.create_local_logdir(args.logdir) run_name = os.path.basename(logdir) gl.event_writer = SummaryWriter(logdir) print(f"Logging to {run_name}") d1 = args.data_width ** 2 assert args.data_width == args.targets_width o = d1 n = args.stats_batch_size d = [d1, 30, 30, 30, 20, 30, 30, 30, d1] # small values for debugging # loss_type = 'LeastSquares' loss_type = 'CrossEntropy' args.wandb = 0 args.stats_steps = 10 args.train_steps = 10 args.stats_batch_size = 10 args.data_width = 2 args.targets_width = 2 args.nonlin = False d1 = args.data_width ** 2 d2 = 2 d3 = args.targets_width ** 2 if loss_type == 'CrossEntropy': d3 = 10 o = d3 n = args.stats_batch_size d = [d1, d2, d3] dsize = max(args.train_batch_size, args.stats_batch_size)+1 model = u.SimpleFullyConnected2(d, bias=True, nonlin=args.nonlin) model = model.to(gl.device) try: # os.environ['WANDB_SILENT'] = 'true' if args.wandb: wandb.init(project='curv_train_tiny', name=run_name) wandb.tensorboard.patch(tensorboardX=False) wandb.config['train_batch'] = args.train_batch_size wandb.config['stats_batch'] = args.stats_batch_size wandb.config['method'] = args.method wandb.config['n'] = n except Exception as e: print(f"wandb crash with {e}") #optimizer = torch.optim.SGD(model.parameters(), lr=0.03, momentum=0.9) optimizer = torch.optim.Adam(model.parameters(), lr=0.03) # make 10x smaller for least-squares loss dataset = u.TinyMNIST(data_width=args.data_width, targets_width=args.targets_width, dataset_size=dsize, original_targets=True) train_loader = torch.utils.data.DataLoader(dataset, batch_size=args.train_batch_size, shuffle=False, drop_last=True) train_iter = u.infinite_iter(train_loader) stats_iter = None if not args.full_batch: stats_loader = torch.utils.data.DataLoader(dataset, batch_size=args.stats_batch_size, shuffle=False, drop_last=True) stats_iter = u.infinite_iter(stats_loader) test_dataset = u.TinyMNIST(data_width=args.data_width, targets_width=args.targets_width, train=False, dataset_size=dsize, original_targets=True) test_loader = torch.utils.data.DataLoader(test_dataset, batch_size=args.train_batch_size, shuffle=False, drop_last=True) test_iter = u.infinite_iter(test_loader) if loss_type == 'LeastSquares': loss_fn = u.least_squares elif loss_type == 'CrossEntropy': loss_fn = nn.CrossEntropyLoss() autograd_lib.add_hooks(model) gl.token_count = 0 last_outer = 0 val_losses = [] for step in range(args.stats_steps): if last_outer: u.log_scalars({"time/outer": 1000*(time.perf_counter() - last_outer)}) last_outer = time.perf_counter() with u.timeit("val_loss"): test_data, test_targets = next(test_iter) test_output = model(test_data) val_loss = loss_fn(test_output, test_targets) print("val_loss", val_loss.item()) val_losses.append(val_loss.item()) u.log_scalar(val_loss=val_loss.item()) # compute stats if args.full_batch: data, targets = dataset.data, dataset.targets else: data, targets = next(stats_iter) # Capture Hessian and gradient stats autograd_lib.enable_hooks() autograd_lib.clear_backprops(model) autograd_lib.clear_hess_backprops(model) with u.timeit("backprop_g"): output = model(data) loss = loss_fn(output, targets) loss.backward(retain_graph=True) with u.timeit("backprop_H"): autograd_lib.backprop_hess(output, hess_type=loss_type) autograd_lib.disable_hooks() # TODO(y): use remove_hooks with u.timeit("compute_grad1"): autograd_lib.compute_grad1(model) with u.timeit("compute_hess"): autograd_lib.compute_hess(model) for (i, layer) in enumerate(model.layers): # input/output layers are unreasonably expensive if not using Kronecker factoring if d[i]>50 or d[i+1]>50: print(f'layer {i} is too big ({d[i],d[i+1]}), skipping stats') continue if args.skip_stats: continue s = AttrDefault(str, {}) # dictionary-like object for layer stats ############################# # Gradient stats ############################# A_t = layer.activations assert A_t.shape == (n, d[i]) # add factor of n because backprop takes loss averaged over batch, while we need per-example loss B_t = layer.backprops_list[0] * n assert B_t.shape == (n, d[i + 1]) with u.timeit(f"khatri_g-{i}"): G = u.khatri_rao_t(B_t, A_t) # batch loss Jacobian assert G.shape == (n, d[i] * d[i + 1]) g = G.sum(dim=0, keepdim=True) / n # average gradient assert g.shape == (1, d[i] * d[i + 1]) u.check_equal(G.reshape(layer.weight.grad1.shape), layer.weight.grad1) if args.autograd_check: u.check_close(B_t.t() @ A_t / n, layer.weight.saved_grad) u.check_close(g.reshape(d[i + 1], d[i]), layer.weight.saved_grad) s.sparsity = torch.sum(layer.output <= 0) / layer.output.numel() # proportion of activations that are zero s.mean_activation = torch.mean(A_t) s.mean_backprop = torch.mean(B_t) # empirical Fisher with u.timeit(f'sigma-{i}'): efisher = G.t() @ G / n sigma = efisher - g.t() @ g s.sigma_l2 = u.sym_l2_norm(sigma) s.sigma_erank = torch.trace(sigma)/s.sigma_l2 lambda_regularizer = args.lmb * torch.eye(d[i + 1]*d[i]).to(gl.device) H = layer.weight.hess with u.timeit(f"invH-{i}"): invH = torch.cholesky_inverse(H+lambda_regularizer) with u.timeit(f"H_l2-{i}"): s.H_l2 = u.sym_l2_norm(H) s.iH_l2 = u.sym_l2_norm(invH) with u.timeit(f"norms-{i}"): s.H_fro = H.flatten().norm() s.iH_fro = invH.flatten().norm() s.grad_fro = g.flatten().norm() s.param_fro = layer.weight.data.flatten().norm() u.nan_check(H) if args.autograd_check: model.zero_grad() output = model(data) loss = loss_fn(output, targets) H_autograd = u.hessian(loss, layer.weight) H_autograd = H_autograd.reshape(d[i] * d[i + 1], d[i] * d[i + 1]) u.check_close(H, H_autograd) # u.dump(sigma, f'/tmp/sigmas/H-{step}-{i}') def loss_direction(dd: torch.Tensor, eps): """loss improvement if we take step eps in direction dd""" return u.to_python_scalar(eps * (dd @ g.t()) - 0.5 * eps ** 2 * dd @ H @ dd.t()) def curv_direction(dd: torch.Tensor): """Curvature in direction dd""" return u.to_python_scalar(dd @ H @ dd.t() / (dd.flatten().norm() ** 2)) with u.timeit(f"pinvH-{i}"): pinvH = u.pinv(H) with u.timeit(f'curv-{i}'): s.grad_curv = curv_direction(g) ndir = g @ pinvH # newton direction s.newton_curv = curv_direction(ndir) setattr(layer.weight, 'pre', pinvH) # save Newton preconditioner s.step_openai = s.grad_fro**2 / s.grad_curv if s.grad_curv else 999 s.step_max = 2 / s.H_l2 s.step_min = torch.tensor(2) / torch.trace(H) s.newton_fro = ndir.flatten().norm() # frobenius norm of Newton update s.regret_newton = u.to_python_scalar(g @ pinvH @ g.t() / 2) # replace with "quadratic_form" s.regret_gradient = loss_direction(g, s.step_openai) with u.timeit(f'rho-{i}'): p_sigma = u.lyapunov_svd(H, sigma) if u.has_nan(p_sigma) and args.compute_rho: # use expensive method print('using expensive method') import pdb; pdb.set_trace() H0, sigma0 = u.to_numpys(H, sigma) p_sigma = scipy.linalg.solve_lyapunov(H0, sigma0) p_sigma = torch.tensor(p_sigma).to(gl.device) if u.has_nan(p_sigma): # import pdb; pdb.set_trace() s.psigma_erank = H.shape[0] s.rho = 1 else: s.psigma_erank = u.sym_erank(p_sigma) s.rho = H.shape[0] / s.psigma_erank with u.timeit(f"batch-{i}"): s.batch_openai = torch.trace(H @ sigma) / (g @ H @ g.t()) s.diversity = torch.norm(G, "fro") ** 2 / torch.norm(g) ** 2 / n # Faster approaches for noise variance computation # s.noise_variance = torch.trace(H.inverse() @ sigma) # try: # # this fails with singular sigma # s.noise_variance = torch.trace(torch.solve(sigma, H)[0]) # # s.noise_variance = torch.trace(torch.lstsq(sigma, H)[0]) # pass # except RuntimeError as _: s.noise_variance_pinv = torch.trace(pinvH @ sigma) s.H_erank = torch.trace(H) / s.H_l2 s.batch_jain_simple = 1 + s.H_erank s.batch_jain_full = 1 + s.rho * s.H_erank u.log_scalars(u.nest_stats(layer.name, s)) # gradient steps with u.timeit('inner'): for i in range(args.train_steps): optimizer.zero_grad() data, targets = next(train_iter) model.zero_grad() output = model(data) loss = loss_fn(output, targets) loss.backward() # u.log_scalar(train_loss=loss.item()) if args.method != 'newton': optimizer.step() if args.weight_decay: for group in optimizer.param_groups: for param in group['params']: param.data.mul_(1-args.weight_decay) else: for (layer_idx, layer) in enumerate(model.layers): param: torch.nn.Parameter = layer.weight param_data: torch.Tensor = param.data param_data.copy_(param_data - 0.1 * param.grad) if layer_idx != 1: # only update 1 layer with Newton, unstable otherwise continue u.nan_check(layer.weight.pre) u.nan_check(param.grad.flatten()) u.nan_check(u.v2r(param.grad.flatten()) @ layer.weight.pre) param_new_flat = u.v2r(param_data.flatten()) - u.v2r(param.grad.flatten()) @ layer.weight.pre u.nan_check(param_new_flat) param_data.copy_(param_new_flat.reshape(param_data.shape)) gl.token_count += data.shape[0] gl.event_writer.close()
def main(): attemp_count = 0 while os.path.exists(f"{args.logdir}{attemp_count:02d}"): attemp_count += 1 logdir = f"{args.logdir}{attemp_count:02d}" run_name = os.path.basename(logdir) gl.event_writer = SummaryWriter(logdir) print(f"Logging to {run_name}") u.seed_random(1) d1 = args.data_width**2 d2 = 10 d3 = args.targets_width**2 o = d3 n = args.stats_batch_size d = [d1, d2, d3] model = u.SimpleFullyConnected(d, nonlin=args.nonlin) model = model.to(gl.device) try: # os.environ['WANDB_SILENT'] = 'true' if args.wandb: wandb.init(project='curv_train_tiny', name=run_name) wandb.tensorboard.patch(tensorboardX=False) wandb.config['train_batch'] = args.train_batch_size wandb.config['stats_batch'] = args.stats_batch_size wandb.config['method'] = args.method wandb.config['d1'] = d1 wandb.config['d2'] = d2 wandb.config['d3'] = d3 wandb.config['n'] = n except Exception as e: print(f"wandb crash with {e}") optimizer = torch.optim.SGD(model.parameters(), lr=0.03, momentum=0.9) dataset = u.TinyMNIST(data_width=args.data_width, targets_width=args.targets_width, dataset_size=args.dataset_size) train_loader = torch.utils.data.DataLoader( dataset, batch_size=args.train_batch_size, shuffle=False, drop_last=True) train_iter = u.infinite_iter(train_loader) stats_loader = torch.utils.data.DataLoader( dataset, batch_size=args.stats_batch_size, shuffle=False, drop_last=True) stats_iter = u.infinite_iter(stats_loader) test_dataset = u.TinyMNIST(data_width=args.data_width, targets_width=args.targets_width, dataset_size=args.dataset_size, train=False) test_loader = torch.utils.data.DataLoader(test_dataset, batch_size=args.stats_batch_size, shuffle=True, drop_last=True) test_iter = u.infinite_iter(test_loader) skip_forward_hooks = False skip_backward_hooks = False def capture_activations(module: nn.Module, input: List[torch.Tensor], output: torch.Tensor): if skip_forward_hooks: return assert not hasattr( module, 'activations' ), "Seeing results of previous autograd, call util.zero_grad to clear" assert len(input) == 1, "this was tested for single input layers only" setattr(module, "activations", input[0].detach()) setattr(module, "output", output.detach()) def capture_backprops(module: nn.Module, _input, output): if skip_backward_hooks: return assert len(output) == 1, "this works for single variable layers only" if gl.backward_idx == 0: assert not hasattr( module, 'backprops' ), "Seeing results of previous autograd, call util.zero_grad to clear" setattr(module, 'backprops', []) assert gl.backward_idx == len(module.backprops) module.backprops.append(output[0]) def save_grad(param: nn.Parameter) -> Callable[[torch.Tensor], None]: """Hook to save gradient into 'param.saved_grad', so it can be accessed after model.zero_grad(). Only stores gradient if the value has not been set, call util.zero_grad to clear it.""" def save_grad_fn(grad): if not hasattr(param, 'saved_grad'): setattr(param, 'saved_grad', grad) return save_grad_fn for layer in model.layers: layer.register_forward_hook(capture_activations) layer.register_backward_hook(capture_backprops) layer.weight.register_hook(save_grad(layer.weight)) def loss_fn(data, targets): err = data - targets.view(-1, data.shape[1]) assert len(data) == len(targets) return torch.sum(err * err) / 2 / len(data) gl.token_count = 0 last_outer = 0 for step in range(args.stats_steps): if last_outer: u.log_scalars( {"time/outer": 1000 * (time.perf_counter() - last_outer)}) last_outer = time.perf_counter() # compute validation loss skip_forward_hooks = True skip_backward_hooks = True with u.timeit("val_loss"): test_data, test_targets = next(test_iter) test_output = model(test_data) val_loss = loss_fn(test_output, test_targets) print("val_loss", val_loss.item()) u.log_scalar(val_loss=val_loss.item()) # compute stats data, targets = next(stats_iter) skip_forward_hooks = False skip_backward_hooks = False # get gradient values with u.timeit("backprop_g"): gl.backward_idx = 0 u.zero_grad(model) output = model(data) loss = loss_fn(output, targets) loss.backward(retain_graph=True) # get Hessian values skip_forward_hooks = True id_mat = torch.eye(o).to(gl.device) u.log_scalar(loss=loss.item()) with u.timeit("backprop_H"): # optionally use randomized low-rank approximation of Hessian hess_rank = args.hess_samples if args.hess_samples else o for out_idx in range(hess_rank): model.zero_grad() # backprop to get section of batch output jacobian for output at position out_idx output = model( data ) # opt: using autograd.grad means I don't have to zero_grad if args.hess_samples: bval = torch.LongTensor(n, o).to(gl.device).random_( 0, 2) * 2 - 1 bval = bval.float() else: ei = id_mat[out_idx] bval = torch.stack([ei] * n) gl.backward_idx = out_idx + 1 output.backward(bval) skip_backward_hooks = True # for (i, layer) in enumerate(model.layers): s = AttrDefault(str, {}) # dictionary-like object for layer stats ############################# # Gradient stats ############################# A_t = layer.activations assert A_t.shape == (n, d[i]) # add factor of n because backprop takes loss averaged over batch, while we need per-example loss B_t = layer.backprops[0] * n assert B_t.shape == (n, d[i + 1]) with u.timeit(f"khatri_g-{i}"): G = u.khatri_rao_t(B_t, A_t) # batch loss Jacobian assert G.shape == (n, d[i] * d[i + 1]) g = G.sum(dim=0, keepdim=True) / n # average gradient assert g.shape == (1, d[i] * d[i + 1]) if args.autograd_check: u.check_close(B_t.t() @ A_t / n, layer.weight.saved_grad) u.check_close(g.reshape(d[i + 1], d[i]), layer.weight.saved_grad) s.sparsity = torch.sum(layer.output <= 0) / layer.output.numel() s.mean_activation = torch.mean(A_t) s.mean_backprop = torch.mean(B_t) # empirical Fisher with u.timeit(f'sigma-{i}'): efisher = G.t() @ G / n sigma = efisher - g.t() @ g s.sigma_l2 = u.sym_l2_norm(sigma) s.sigma_erank = torch.trace(sigma) / s.sigma_l2 ############################# # Hessian stats ############################# A_t = layer.activations Bh_t = [ layer.backprops[out_idx + 1] for out_idx in range(hess_rank) ] Amat_t = torch.cat([A_t] * hess_rank, dim=0) Bmat_t = torch.cat(Bh_t, dim=0) assert Amat_t.shape == (n * hess_rank, d[i]) assert Bmat_t.shape == (n * hess_rank, d[i + 1]) lambda_regularizer = args.lmb * torch.eye(d[i] * d[i + 1]).to( gl.device) with u.timeit(f"khatri_H-{i}"): Jb = u.khatri_rao_t( Bmat_t, Amat_t) # batch Jacobian, in row-vec format with u.timeit(f"H-{i}"): H = Jb.t() @ Jb / n with u.timeit(f"invH-{i}"): invH = torch.cholesky_inverse(H + lambda_regularizer) with u.timeit(f"H_l2-{i}"): s.H_l2 = u.sym_l2_norm(H) s.iH_l2 = u.sym_l2_norm(invH) with u.timeit(f"norms-{i}"): s.H_fro = H.flatten().norm() s.iH_fro = invH.flatten().norm() s.jacobian_fro = Jb.flatten().norm() s.grad_fro = g.flatten().norm() s.param_fro = layer.weight.data.flatten().norm() u.nan_check(H) if args.autograd_check: model.zero_grad() output = model(data) loss = loss_fn(output, targets) H_autograd = u.hessian(loss, layer.weight) H_autograd = H_autograd.reshape(d[i] * d[i + 1], d[i] * d[i + 1]) u.check_close(H, H_autograd) # u.dump(sigma, f'/tmp/sigmas/H-{step}-{i}') def loss_direction(dd: torch.Tensor, eps): """loss improvement if we take step eps in direction dd""" return u.to_python_scalar(eps * (dd @ g.t()) - 0.5 * eps**2 * dd @ H @ dd.t()) def curv_direction(dd: torch.Tensor): """Curvature in direction dd""" return u.to_python_scalar(dd @ H @ dd.t() / (dd.flatten().norm()**2)) with u.timeit("pinvH"): pinvH = u.pinv(H) with u.timeit(f'curv-{i}'): s.regret_newton = u.to_python_scalar(g @ pinvH @ g.t() / 2) s.grad_curv = curv_direction(g) ndir = g @ pinvH # newton direction s.newton_curv = curv_direction(ndir) setattr(layer.weight, 'pre', pinvH) # save Newton preconditioner s.step_openai = 1 / s.grad_curv if s.grad_curv else 999 s.step_max = 2 / u.sym_l2_norm(H) s.step_min = torch.tensor(2) / torch.trace(H) s.newton_fro = ndir.flatten().norm( ) # frobenius norm of Newton update s.regret_gradient = loss_direction(g, s.step_openai) with u.timeit(f'rho-{i}'): p_sigma = u.lyapunov_svd(H, sigma) if u.has_nan( p_sigma) and args.compute_rho: # use expensive method H0 = H.cpu().detach().numpy() sigma0 = sigma.cpu().detach().numpy() p_sigma = scipy.linalg.solve_lyapunov(H0, sigma0) p_sigma = torch.tensor(p_sigma).to(gl.device) if u.has_nan(p_sigma): s.psigma_erank = H.shape[0] s.rho = 1 else: s.psigma_erank = u.sym_erank(p_sigma) s.rho = H.shape[0] / s.psigma_erank with u.timeit(f"batch-{i}"): s.batch_openai = torch.trace(H @ sigma) / (g @ H @ g.t()) print('openai batch', s.batch_openai) s.diversity = torch.norm(G, "fro")**2 / torch.norm(g)**2 # s.noise_variance = torch.trace(H.inverse() @ sigma) # try: # # this fails with singular sigma # s.noise_variance = torch.trace(torch.solve(sigma, H)[0]) # # s.noise_variance = torch.trace(torch.lstsq(sigma, H)[0]) # pass # except RuntimeError as _: s.noise_variance_pinv = torch.trace(pinvH @ sigma) s.H_erank = torch.trace(H) / s.H_l2 s.batch_jain_simple = 1 + s.H_erank s.batch_jain_full = 1 + s.rho * s.H_erank u.log_scalars(u.nest_stats(layer.name, s)) # gradient steps last_inner = 0 for i in range(args.train_steps): if last_inner: u.log_scalars( {"time/inner": 1000 * (time.perf_counter() - last_inner)}) last_inner = time.perf_counter() optimizer.zero_grad() data, targets = next(train_iter) model.zero_grad() output = model(data) loss = loss_fn(output, targets) loss.backward() u.log_scalar(train_loss=loss.item()) if args.method != 'newton': optimizer.step() else: for (layer_idx, layer) in enumerate(model.layers): param: torch.nn.Parameter = layer.weight param_data: torch.Tensor = param.data param_data.copy_(param_data - 0.1 * param.grad) if layer_idx != 1: # only update 1 layer with Newton, unstable otherwise continue u.nan_check(layer.weight.pre) u.nan_check(param.grad.flatten()) u.nan_check(u.v2r(param.grad.flatten()) @ layer.weight.pre) param_new_flat = u.v2r(param_data.flatten()) - u.v2r( param.grad.flatten()) @ layer.weight.pre u.nan_check(param_new_flat) param_data.copy_(param_new_flat.reshape(param_data.shape)) gl.token_count += data.shape[0] gl.event_writer.close()
def main(): u.install_pdb_handler() u.seed_random(1) logdir = u.create_local_logdir(args.logdir) run_name = os.path.basename(logdir) gl.event_writer = SummaryWriter(logdir) print(f"Logging to {logdir}") loss_type = 'CrossEntropy' d1 = args.data_width ** 2 args.stats_batch_size = min(args.stats_batch_size, args.dataset_size) args.train_batch_size = min(args.train_batch_size, args.dataset_size) n = args.stats_batch_size o = 10 d = [d1, 60, 60, 60, o] # dataset_size = args.dataset_size model = u.SimpleFullyConnected2(d, bias=True, nonlin=args.nonlin, last_layer_linear=True) model = model.to(gl.device) u.mark_expensive(model.layers[0]) # to stop grad1/hess calculations on this layer print(model) try: if args.wandb: wandb.init(project='curv_train_tiny', name=run_name, dir='/tmp/wandb.runs') wandb.tensorboard.patch(tensorboardX=False) wandb.config['train_batch'] = args.train_batch_size wandb.config['stats_batch'] = args.stats_batch_size wandb.config['n'] = n except Exception as e: print(f"wandb crash with {e}") optimizer = torch.optim.SGD(model.parameters(), lr=args.lr, momentum=0.9) # optimizer = torch.optim.Adam(model.parameters(), lr=0.03) # make 10x smaller for least-squares loss dataset = u.TinyMNIST(data_width=args.data_width, dataset_size=args.dataset_size, loss_type=loss_type) train_loader = torch.utils.data.DataLoader(dataset, batch_size=args.train_batch_size, shuffle=False, drop_last=True) train_iter = u.infinite_iter(train_loader) stats_loader = torch.utils.data.DataLoader(dataset, batch_size=args.stats_batch_size, shuffle=False, drop_last=True) stats_iter = u.infinite_iter(stats_loader) stats_data, stats_targets = next(stats_iter) test_dataset = u.TinyMNIST(data_width=args.data_width, train=False, dataset_size=args.dataset_size, loss_type=loss_type) test_batch_size = min(args.dataset_size, 1000) test_loader = torch.utils.data.DataLoader(test_dataset, batch_size=test_batch_size, shuffle=False, drop_last=True) test_iter = u.infinite_iter(test_loader) if loss_type == 'LeastSquares': loss_fn = u.least_squares else: # loss_type == 'CrossEntropy': loss_fn = nn.CrossEntropyLoss() autograd_lib.add_hooks(model) gl.reset_global_step() last_outer = 0 val_losses = [] for step in range(args.stats_steps): if last_outer: u.log_scalars({"time/outer": 1000*(time.perf_counter() - last_outer)}) last_outer = time.perf_counter() with u.timeit("val_loss"): test_data, test_targets = next(test_iter) test_output = model(test_data) val_loss = loss_fn(test_output, test_targets) print("val_loss", val_loss.item()) val_losses.append(val_loss.item()) u.log_scalar(val_loss=val_loss.item()) with u.timeit("validate"): if loss_type == 'CrossEntropy': val_accuracy, val_loss = validate(model, test_loader, f'test (stats_step {step})') # train_accuracy, train_loss = validate(model, train_loader, f'train (stats_step {step})') metrics = {'stats_step': step, 'val_accuracy': val_accuracy, 'val_loss': val_loss} u.log_scalars(metrics) data, targets = stats_data, stats_targets if not args.skip_stats: # Capture Hessian and gradient stats autograd_lib.enable_hooks() autograd_lib.clear_backprops(model) autograd_lib.clear_hess_backprops(model) with u.timeit("backprop_g"): output = model(data) loss = loss_fn(output, targets) loss.backward(retain_graph=True) with u.timeit("backprop_H"): autograd_lib.backprop_hess(output, hess_type=loss_type) autograd_lib.disable_hooks() # TODO(y): use remove_hooks with u.timeit("compute_grad1"): autograd_lib.compute_grad1(model) with u.timeit("compute_hess"): autograd_lib.compute_hess(model) for (i, layer) in enumerate(model.layers): if hasattr(layer, 'expensive'): continue param_names = {layer.weight: "weight", layer.bias: "bias"} for param in [layer.weight, layer.bias]: # input/output layers are unreasonably expensive if not using Kronecker factoring if d[i]*d[i+1] > 8000: print(f'layer {i} is too big ({d[i],d[i+1]}), skipping stats') continue s = AttrDefault(str, {}) # dictionary-like object for layer stats ############################# # Gradient stats ############################# A_t = layer.activations B_t = layer.backprops_list[0] * n s.sparsity = torch.sum(layer.output <= 0) / layer.output.numel() # proportion of activations that are zero s.mean_activation = torch.mean(A_t) s.mean_backprop = torch.mean(B_t) # empirical Fisher G = param.grad1.reshape((n, -1)) g = G.mean(dim=0, keepdim=True) u.nan_check(G) with u.timeit(f'sigma-{i}'): efisher = G.t() @ G / n sigma = efisher - g.t() @ g # sigma_spectrum = s.sigma_l2 = u.sym_l2_norm(sigma) s.sigma_erank = torch.trace(sigma)/s.sigma_l2 H = param.hess lambda_regularizer = args.lmb * torch.eye(H.shape[0]).to(gl.device) u.nan_check(H) with u.timeit(f"invH-{i}"): invH = torch.cholesky_inverse(H+lambda_regularizer) with u.timeit(f"H_l2-{i}"): s.H_l2 = u.sym_l2_norm(H) s.iH_l2 = u.sym_l2_norm(invH) with u.timeit(f"norms-{i}"): s.H_fro = H.flatten().norm() s.iH_fro = invH.flatten().norm() s.grad_fro = g.flatten().norm() s.param_fro = param.data.flatten().norm() def loss_direction(dd: torch.Tensor, eps): """loss improvement if we take step eps in direction dd""" return u.to_python_scalar(eps * (dd @ g.t()) - 0.5 * eps ** 2 * dd @ H @ dd.t()) def curv_direction(dd: torch.Tensor): """Curvature in direction dd""" return u.to_python_scalar(dd @ H @ dd.t() / (dd.flatten().norm() ** 2)) with u.timeit(f"pinvH-{i}"): pinvH = u.pinv(H) with u.timeit(f'curv-{i}'): s.grad_curv = curv_direction(g) # curvature (eigenvalue) in direction g ndir = g @ pinvH # newton direction s.newton_curv = curv_direction(ndir) setattr(layer.weight, 'pre', pinvH) # save Newton preconditioner s.step_openai = 1 / s.grad_curv if s.grad_curv else 1234567 s.step_div_inf = 2 / s.H_l2 # divegent step size for batch_size=infinity s.step_div_1 = torch.tensor(2) / torch.trace(H) # divergent step for batch_size=1 s.newton_fro = ndir.flatten().norm() # frobenius norm of Newton update s.regret_newton = u.to_python_scalar(g @ pinvH @ g.t() / 2) # replace with "quadratic_form" s.regret_gradient = loss_direction(g, s.step_openai) with u.timeit(f'rho-{i}'): s.rho, s.lyap_erank, lyap_evals = u.truncated_lyapunov_rho(H, sigma) s.step_div_1_adjusted = s.step_div_1/s.rho with u.timeit(f"batch-{i}"): s.batch_openai = torch.trace(H @ sigma) / (g @ H @ g.t()) s.diversity = torch.norm(G, "fro") ** 2 / torch.norm(g) ** 2 / n # Gradient diversity / n s.noise_variance_pinv = torch.trace(pinvH @ sigma) s.H_erank = torch.trace(H) / s.H_l2 s.batch_jain_simple = 1 + s.H_erank s.batch_jain_full = 1 + s.rho * s.H_erank param_name = f"{layer.name}={param_names[param]}" u.log_scalars(u.nest_stats(f"{param_name}", s)) H_evals = u.symeig_pos_evals(H) sigma_evals = u.symeig_pos_evals(sigma) u.log_spectrum(f'{param_name}/hess', H_evals) u.log_spectrum(f'{param_name}/sigma', sigma_evals) u.log_spectrum(f'{param_name}/lyap', lyap_evals) # gradient steps with u.timeit('inner'): for i in range(args.train_steps): optimizer.zero_grad() data, targets = next(train_iter) model.zero_grad() output = model(data) loss = loss_fn(output, targets) loss.backward() optimizer.step() if args.weight_decay: for group in optimizer.param_groups: for param in group['params']: param.data.mul_(1-args.weight_decay) gl.increment_global_step(data.shape[0]) gl.event_writer.close()
def main(): parser = argparse.ArgumentParser(description='PyTorch MNIST Example') parser.add_argument('--batch-size', type=int, default=64, metavar='N', help='input batch size for training (default: 64)') parser.add_argument('--test-batch-size', type=int, default=1000, metavar='N', help='input batch size for testing (default: 1000)') parser.add_argument('--epochs', type=int, default=10, metavar='N', help='number of epochs to train (default: 10)') parser.add_argument('--no-cuda', action='store_true', default=False, help='disables CUDA training') parser.add_argument('--seed', type=int, default=1, metavar='S', help='random seed (default: 1)') parser.add_argument( '--log-interval', type=int, default=10, metavar='N', help='how many batches to wait before logging training status') parser.add_argument('--save-model', action='store_true', default=False, help='For Saving the current Model') parser.add_argument('--wandb', type=int, default=1, help='log to weights and biases') parser.add_argument('--autograd_check', type=int, default=0, help='autograd correctness checks') parser.add_argument('--logdir', type=str, default='/tmp/runs/curv_train_tiny/run') parser.add_argument('--nonlin', type=int, default=1, help="whether to add ReLU nonlinearity between layers") parser.add_argument('--bias', type=int, default=1, help="whether to add bias between layers") parser.add_argument('--layer', type=int, default=-1, help="restrict updates to this layer") parser.add_argument('--data_width', type=int, default=28) parser.add_argument('--targets_width', type=int, default=28) parser.add_argument( '--hess_samples', type=int, default=1, help='number of samples when sub-sampling outputs, 0 for exact hessian' ) parser.add_argument('--hess_kfac', type=int, default=0, help='whether to use KFAC approximation for hessian') parser.add_argument('--compute_rho', type=int, default=0, help='use expensive method to compute rho') parser.add_argument('--skip_stats', type=int, default=1, help='skip all stats collection') parser.add_argument('--dataset_size', type=int, default=60000) parser.add_argument('--train_steps', type=int, default=5, help="this many train steps between stat collection") parser.add_argument('--stats_steps', type=int, default=1000000, help="total number of curvature stats collections") parser.add_argument('--full_batch', type=int, default=0, help='do stats on the whole dataset') parser.add_argument('--train_batch_size', type=int, default=64) parser.add_argument('--stats_batch_size', type=int, default=10000) parser.add_argument('--lr', type=float, default=1e-3) parser.add_argument('--weight_decay', type=float, default=1e-5) parser.add_argument('--momentum', type=float, default=0.9) parser.add_argument('--dropout', type=int, default=0) parser.add_argument('--swa', type=int, default=1) parser.add_argument('--lmb', type=float, default=1e-3) parser.add_argument('--uniform', type=int, default=0, help="all layers same size") parser.add_argument('--redundancy', type=int, default=0, help="duplicate all layers this many times") args = parser.parse_args() attemp_count = 0 while os.path.exists(f"{args.logdir}{attemp_count:02d}"): attemp_count += 1 logdir = f"{args.logdir}{attemp_count:02d}" run_name = os.path.basename(logdir) gl.event_writer = SummaryWriter(logdir) print(f"Logging to {run_name}") u.seed_random(1) d1 = 28 * 28 if args.uniform: d = [784, 784, 784, 784, 784, 784, 10] else: d = [784, 2500, 2000, 1500, 1000, 500, 10] o = 10 n = args.stats_batch_size if args.redundancy: model = u.RedundantFullyConnected2(d, nonlin=args.nonlin, bias=args.bias, dropout=args.dropout, redundancy=args.redundancy) else: model = u.SimpleFullyConnected2(d, nonlin=args.nonlin, bias=args.bias, dropout=args.dropout) model = model.to(gl.device) try: # os.environ['WANDB_SILENT'] = 'true' if args.wandb: wandb.init(project='train_ciresan', name=run_name) wandb.tensorboard.patch(tensorboardX=False) wandb.config['train_batch'] = args.train_batch_size wandb.config['stats_batch'] = args.stats_batch_size wandb.config['redundancy'] = args.redundancy except Exception as e: print(f"wandb crash with {e}") optimizer = torch.optim.SGD(model.parameters(), lr=args.lr, momentum=args.momentum) dataset = u.TinyMNIST(data_width=args.data_width, targets_width=args.targets_width, original_targets=True, dataset_size=args.dataset_size) train_loader = torch.utils.data.DataLoader( dataset, batch_size=args.train_batch_size, shuffle=True, drop_last=True) train_iter = u.infinite_iter(train_loader) assert not args.full_batch, "fixme: validation still uses stats_iter" if not args.full_batch: stats_loader = torch.utils.data.DataLoader( dataset, batch_size=args.stats_batch_size, shuffle=False, drop_last=True) stats_iter = u.infinite_iter(stats_loader) else: stats_iter = None test_dataset = u.TinyMNIST(data_width=args.data_width, targets_width=args.targets_width, train=False, original_targets=True, dataset_size=args.dataset_size) test_loader = torch.utils.data.DataLoader(test_dataset, batch_size=args.stats_batch_size, shuffle=False, drop_last=False) loss_fn = torch.nn.CrossEntropyLoss() gl.token_count = 0 last_outer = 0 for step in range(args.stats_steps): epoch = gl.token_count // 60000 print(gl.token_count) if last_outer: u.log_scalars( {"time/outer": 1000 * (time.perf_counter() - last_outer)}) last_outer = time.perf_counter() # compute validation loss model.eval() if args.swa: with u.timeit('swa'): base_opt = torch.optim.SGD(model.parameters(), lr=args.lr, momentum=args.momentum) opt = torchcontrib.optim.SWA(base_opt, swa_start=0, swa_freq=1, swa_lr=args.lr) for _ in range(100): optimizer.zero_grad() data, targets = next(train_iter) model.zero_grad() output = model(data) loss = loss_fn(output, targets) loss.backward() opt.step() opt.swap_swa_sgd() with u.timeit("validate"): val_accuracy, val_loss = validate(model, test_loader, f'test (epoch {epoch})') train_accuracy, train_loss = validate(model, stats_loader, f'train (epoch {epoch})') # save log metrics = { 'epoch': epoch, 'val_accuracy': val_accuracy, 'val_loss': val_loss, 'train_loss': train_loss, 'train_accuracy': train_accuracy, 'lr': optimizer.param_groups[0]['lr'], 'momentum': optimizer.param_groups[0].get('momentum', 0) } u.log_scalars(metrics) # compute stats if args.full_batch: data, targets = dataset.data, dataset.targets else: data, targets = next(stats_iter) model.skip_forward_hooks = False model.skip_backward_hooks = False # get gradient values with u.timeit("backprop_g"): gl.backward_idx = 0 u.clear_backprops(model) output = model(data) loss = loss_fn(output, targets) loss.backward(retain_graph=True) u.log_scalar(loss=loss.item()) # get Hessian values hessian_activations = [] hessian_backprops = [] hessians = [] # list of Hessians in Kronecker form model.skip_forward_hooks = True for (i, layer) in enumerate(model.layers): if args.skip_stats: continue s = AttrDefault(str, {}) # dictionary-like object for layer stats ############################# # Gradient stats ############################# A_t = layer.activations assert A_t.shape == (n, d[i]) # add factor of n because backprop takes loss averaged over batch, while we need per-example loss B_t = layer.backprops[0] * n assert B_t.shape == (n, d[i + 1]) G = (B_t, A_t) # g = G.sum(dim=0, keepdim=True) / n # average gradient g = u.kron_sum(G) / n assert g.shape == (1, d[i] * d[i + 1]) s.sparsity = torch.sum(layer.output <= 0) / layer.output.numel() s.mean_activation = torch.mean(A_t) s.mean_backprop = torch.mean(B_t) # empirical Fisher with u.timeit(f'sigma-{i}'): # efisher = u.kron_cov(G) # G.t() @ G / n sigma = u.kron_sigma(G, g) # efisher - g.t() @ g s.sigma_l2 = u.kron_sym_l2_norm(sigma) s.sigma_erank = u.kron_trace( sigma) / s.sigma_l2 # torch.trace(sigma)/s.sigma_l2 ############################# # Hessian stats ############################# # this is a pair of left/right Kronecker fctors H = hessians[i] with u.timeit(f"invH-{i}"): invH = u.kron_inverse(H) with u.timeit(f"H_l2-{i}"): s.H_l2 = u.kron_sym_l2_norm(H) s.iH_l2 = u.kron_sym_l2_norm(invH) with u.timeit(f"norms-{i}"): s.H_fro = u.kron_fro_norm(H) s.invH_fro = u.kron_fro_norm(invH) s.grad_fro = u.kron_fro_norm(g) # g.flatten().norm() s.param_fro = layer.weight.data.flatten().norm() u.kron_nan_check(H) with u.timeit(f"pinvH-{i}"): pinvH = u.kron_pinv(H) def kron_curv_direction(dd: torch.Tensor): """Curvature in direction dd, using factored form""" # dd @ H @ dd.t(), computed by kron_quadratic_form(H, dd) return u.to_python_scalar( u.kron_quadratic_form(H, dd) / (dd.flatten().norm()**2)) def kron_loss_direction(dd: torch.Tensor, eps): """loss improvement if we take step eps in direction dd""" # kron_matmul(dd, g) = dd @ g.t() return u.to_python_scalar(eps * (u.kron_matmul(dd, g)) - 0.5 * eps**2 * u.kron_quadratic_form(H, dd)) with u.timeit(f'curv-{i}'): s.grad_curv = kron_curv_direction(g) s.step_openai = 1 / s.grad_curv if s.grad_curv else 999 s.step_max = 2 / s.H_l2 s.step_min = torch.tensor(2) / u.kron_trace(H) s.regret_gradient = kron_loss_direction(g, s.step_openai) with u.timeit(f"batch-{i}"): # torch.trace(H @ sigma) # (g @ H @ g.t()) s.batch_openai = u.kron_trace_matmul( H, sigma) / u.kron_quadratic_form(H, g) s.diversity = torch.norm(G, "fro")**2 / torch.norm(g)**2 # torch.trace(H) s.H_erank = u.kron_trace(H) / s.H_l2 s.batch_jain_simple = 1 + s.H_erank u.log_scalars(u.nest_stats(layer.name, s)) # gradient steps model.train() last_inner = 0 for i in range(args.train_steps): if last_inner: u.log_scalars( {"time/inner": 1000 * (time.perf_counter() - last_inner)}) last_inner = time.perf_counter() optimizer.zero_grad() data, targets = next(train_iter) model.zero_grad() output = model(data) loss = loss_fn(output, targets) loss.backward() optimizer.step() if args.weight_decay: for group in optimizer.param_groups: for param in group['params']: param.data.mul_(1 - args.weight_decay) gl.token_count += data.shape[0] gl.event_writer.close()