def test_adam(): N_weights = 5 W0 = 0.1 * npr.randn(N_weights) (loss_fun, true_argmin) = make_optimization_problem(N_weights) x_min = adam(grad(loss_fun), W0) assert np.allclose(x_min, true_argmin, rtol=1e-3, atol=1e-4), \ "Diffs are: {0}".format(x_min - true_argmin)
def run(): train_data, valid_data, tests_data = load_data_dicts( N_train, N_valid, N_tests) parser, pred_fun, loss_fun, frac_err = make_nn_funs(layer_sizes) N_weight_types = len(parser.names) N_weights = len(parser.vect) hyperparams = VectorParser() rs = RandomState((seed)) hyperparams['log_L2_reg'] = np.full(N_weights, init_log_L2_reg)\ + rs.randn(N_weights) * init_log_L2_reg_noise hyperparams['log_param_scale'] = np.full(N_weight_types, init_log_param_scale) hyperparams['log_alphas'] = np.full((N_iters, N_weight_types), init_log_alphas) hyperparams['invlogit_betas'] = np.full((N_iters, N_weight_types), init_invlogit_betas) cur_primal_results = {} def primal_optimizer(hyperparam_vect, i_hyper): def indexed_loss_fun(w, L2_vect, i_iter): rs = RandomState( (seed, i_hyper, i_iter)) # Deterministic seed needed for backwards pass. idxs = rs.randint(N_train, size=batch_size) return loss_fun(w, train_data['X'][idxs], train_data['T'][idxs], L2_vect) learning_curve_dict = defaultdict(list) def callback(x, v, g, i_iter): if i_iter % thin == 0: learning_curve_dict['learning_curve'].append( loss_fun(x, **train_data)) learning_curve_dict['grad_norm'].append(np.linalg.norm(g)) learning_curve_dict['weight_norm'].append(np.linalg.norm(x)) learning_curve_dict['velocity_norm'].append(np.linalg.norm(v)) cur_hyperparams = hyperparams.new_vect(hyperparam_vect) rs = RandomState((seed, i_hyper)) W0 = fill_parser(parser, np.exp(cur_hyperparams['log_param_scale'])) W0 *= rs.randn(W0.size) alphas = np.exp(cur_hyperparams['log_alphas']) betas = logit(cur_hyperparams['invlogit_betas']) L2_reg = np.exp(cur_hyperparams['log_L2_reg']) W_opt = sgd_parsed(grad(indexed_loss_fun), kylist(W0, alphas, betas, L2_reg), parser, callback=callback) cur_primal_results['weights'] = getval(W_opt).copy() cur_primal_results['learning_curve'] = getval(learning_curve_dict) return W_opt, learning_curve_dict def hyperloss(hyperparam_vect, i_hyper): W_opt, _ = primal_optimizer(hyperparam_vect, i_hyper) return loss_fun(W_opt, **valid_data) hyperloss_grad = grad(hyperloss) meta_results = defaultdict(list) old_metagrad = [np.ones(hyperparams.vect.size)] def meta_callback(hyperparam_vect, i_hyper, metagrad=None): #x, learning_curve_dict = primal_optimizer(hyperparam_vect, i_hyper) x, learning_curve_dict = cur_primal_results[ 'weights'], cur_primal_results['learning_curve'] cur_hyperparams = hyperparams.new_vect(hyperparam_vect.copy()) for field in cur_hyperparams.names: meta_results[field] = cur_hyperparams[field] meta_results['train_loss'].append(loss_fun(x, **train_data)) meta_results['valid_loss'].append(loss_fun(x, **valid_data)) meta_results['tests_loss'].append(loss_fun(x, **tests_data)) meta_results['test_err'].append(frac_err(x, **tests_data)) meta_results['learning_curves'].append(learning_curve_dict) meta_results['example_weights'] = x if metagrad is not None: meta_results['meta_grad_magnitude'].append( np.linalg.norm(metagrad)) meta_results['meta_grad_angle'].append(np.dot(old_metagrad[0], metagrad) \ / (np.linalg.norm(metagrad)* np.linalg.norm(old_metagrad[0]))) old_metagrad[0] = metagrad print "Meta Epoch {0} Train loss {1:2.4f} Valid Loss {2:2.4f}" \ " Test Loss {3:2.4f} Test Err {4:2.4f}".format( i_hyper, meta_results['train_loss'][-1], meta_results['valid_loss'][-1], meta_results['tests_loss'][-1], meta_results['test_err'][-1]) initial_hypergrad = hyperloss_grad(hyperparams.vect, 0) parsed_init_hypergrad = hyperparams.new_vect(initial_hypergrad.copy()) final_result = adam(hyperloss_grad, hyperparams.vect, meta_callback, N_meta_iter, meta_alpha) meta_callback(final_result, N_meta_iter) parser.vect = None # No need to pickle zeros return meta_results, parser, parsed_init_hypergrad
def run(): train_data, valid_data, tests_data = load_data_dicts(N_train, N_valid, N_tests) parser, pred_fun, loss_fun, frac_err = make_nn_funs(layer_sizes) N_weight_types = len(parser.names) hyperparams = VectorParser() hyperparams['log_param_scale'] = np.full(N_weight_types, init_log_param_scale) hyperparams['log_alphas'] = np.full(N_iters, init_log_alphas) hyperparams['invlogit_betas'] = np.full(N_iters, init_invlogit_betas) fixed_hyperparams = VectorParser() fixed_hyperparams['log_L2_reg'] = np.full(N_weight_types, init_log_L2_reg) # TODO: memoize def primal_optimizer(hyperparam_vect, i_hyper): def indexed_loss_fun(w, L2_vect, i_iter): rs = RandomState((seed, i_hyper, i_iter)) # Deterministic seed needed for backwards pass. idxs = rs.randint(N_train, size=batch_size) return loss_fun(w, train_data['X'][idxs], train_data['T'][idxs], L2_vect) learning_curve_dict = defaultdict(list) def callback(x, v, g, i_iter): if i_iter % thin == 0: learning_curve_dict['learning_curve'].append(loss_fun(x, **train_data)) learning_curve_dict['grad_norm'].append(np.linalg.norm(g)) learning_curve_dict['weight_norm'].append(np.linalg.norm(x)) learning_curve_dict['velocity_norm'].append(np.linalg.norm(v)) cur_hyperparams = hyperparams.new_vect(hyperparam_vect) rs = RandomState((seed, i_hyper)) W0 = fill_parser(parser, np.exp(cur_hyperparams['log_param_scale'])) W0 *= rs.randn(W0.size) alphas = np.exp(cur_hyperparams['log_alphas']) betas = logit(cur_hyperparams['invlogit_betas']) L2_reg = fill_parser(parser, np.exp(fixed_hyperparams['log_L2_reg'])) W_opt = sgd4(grad(indexed_loss_fun), kylist(W0, alphas, betas, L2_reg), callback) #callback(W_opt, N_iters) return W_opt, learning_curve_dict def hyperloss(hyperparam_vect, i_hyper): W_opt, _ = primal_optimizer(hyperparam_vect, i_hyper) return loss_fun(W_opt, **train_data) hyperloss_grad = grad(hyperloss) meta_results = defaultdict(list) old_metagrad = [np.ones(hyperparams.vect.size)] def meta_callback(hyperparam_vect, i_hyper, metagrad): x, learning_curve_dict = primal_optimizer(hyperparam_vect, i_hyper) cur_hyperparams = hyperparams.new_vect(hyperparam_vect.copy()) for field in cur_hyperparams.names: meta_results[field].append(cur_hyperparams[field]) meta_results['train_loss'].append(loss_fun(x, **train_data)) meta_results['valid_loss'].append(loss_fun(x, **valid_data)) meta_results['tests_loss'].append(loss_fun(x, **tests_data)) meta_results['test_err'].append(frac_err(x, **tests_data)) meta_results['learning_curves'].append(learning_curve_dict) meta_results['meta_grad_magnitude'].append(np.linalg.norm(metagrad)) meta_results['meta_grad_angle'].append(np.dot(old_metagrad[0], metagrad) \ / (np.linalg.norm(metagrad)* np.linalg.norm(old_metagrad[0]))) old_metagrad[0] = metagrad print "Meta Epoch {0} Train loss {1:2.4f} Valid Loss {2:2.4f}" \ " Test Loss {3:2.4f} Test Err {4:2.4f}".format( i_hyper, meta_results['train_loss'][-1], meta_results['valid_loss'][-1], meta_results['train_loss'][-1], meta_results['test_err'][-1]) final_result = adam(hyperloss_grad, hyperparams.vect, meta_callback, N_meta_iter, meta_alpha) meta_callback(final_result, N_meta_iter, np.ones(hyperparams.vect.size)) # Fake final gradient. parser.vect = None # No need to pickle zeros return meta_results, parser
def run(): train_data, valid_data, tests_data = load_data_dicts(N_train, N_valid, N_tests) parser, pred_fun, loss_fun, frac_err = make_nn_funs(layer_sizes) N_weight_types = len(parser.names) rs = RandomState((seed)) init_fake_data = rs.randn(*(train_data['X'].shape)) * init_fake_data_scale one_hot = lambda x, K : np.array(x[:,None] == np.arange(K)[None, :], dtype=int) fake_labels = one_hot(np.array(range(N_train)) % N_classes, N_classes) # One of each. hyperparams = VectorParser() hyperparams['fake_data'] = init_fake_data fixed_hyperparams = VectorParser() fixed_hyperparams['log_param_scale'] = np.full(N_weight_types, init_log_param_scale) fixed_hyperparams['log_alphas'] = np.full((N_iters, N_weight_types), init_log_alphas) fixed_hyperparams['invlogit_betas'] = np.full((N_iters, N_weight_types), init_invlogit_betas) fixed_hyperparams['log_L2_reg'] = np.full(N_weight_types, init_log_L2_reg) cur_primal_results = {} loss_meta_parser = VectorParser() loss_meta_parser[''] def primal_optimizer(hyperparam_vect, i_hyper): def indexed_loss_fun(w, meta_vect, i_iter): (train_data, train_labels, L2_vect) = meta return loss_fun(w, train_data, train_labels, L2_vect) #return loss_fun(w, train_data['X'], train_data['T'], L2_vect + np.sum(fake_data.ravel())) learning_curve_dict = defaultdict(list) def callback(x, v, g, i_iter): if i_iter % thin == 0: # learning_curve_dict['learning_curve'].append(loss_fun(x, getval(cur_hyperparams['fake_data']), fake_labels)) learning_curve_dict['grad_norm'].append(np.linalg.norm(g)) learning_curve_dict['weight_norm'].append(np.linalg.norm(x)) learning_curve_dict['velocity_norm'].append(np.linalg.norm(v)) cur_hyperparams = hyperparams.new_vect(hyperparam_vect) fake_data = cur_hyperparams['fake_data'] rs = RandomState((seed, i_hyper)) W0 = fill_parser(parser, np.exp(fixed_hyperparams['log_param_scale'])) W0 *= rs.randn(W0.size) alphas = np.exp(fixed_hyperparams['log_alphas']) betas = logit(fixed_hyperparams['invlogit_betas']) L2_reg = fill_parser(parser, np.exp(fixed_hyperparams['log_L2_reg'])) meta = kylist(fake_data, fake_labels, L2_reg) W_opt = sgd_parsed(grad(indexed_loss_fun), kylist(W0, alphas, betas, meta), parser, callback=callback) cur_primal_results['weights'] = getval(W_opt).copy() cur_primal_results['learning_curve'] = getval(learning_curve_dict) return W_opt, learning_curve_dict def hyperloss(hyperparam_vect, i_hyper): W_opt, _ = primal_optimizer(hyperparam_vect, i_hyper) return loss_fun(W_opt, **valid_data) hyperloss_grad = grad(hyperloss) meta_results = defaultdict(list) old_metagrad = [np.ones(hyperparams.vect.size)] def meta_callback(hyperparam_vect, i_hyper, metagrad=None): x, learning_curve_dict = cur_primal_results['weights'], cur_primal_results['learning_curve'] cur_hyperparams = hyperparams.new_vect(hyperparam_vect.copy()) for field in cur_hyperparams.names: meta_results[field].append(cur_hyperparams[field]) #meta_results['train_loss'].append(loss_fun(x, getval(cur_hyperparams['fake_data']), fake_labels)) meta_results['train_loss'].append(0) meta_results['valid_loss'].append(loss_fun(x, **valid_data)) meta_results['tests_loss'].append(loss_fun(x, **tests_data)) meta_results['test_err'].append(frac_err(x, **tests_data)) meta_results['learning_curves'].append(learning_curve_dict) meta_results['example_weights'] = x if metagrad is not None: print metagrad meta_results['meta_grad_magnitude'].append(np.linalg.norm(metagrad)) meta_results['meta_grad_angle'].append(np.dot(old_metagrad[0], metagrad) \ / (np.linalg.norm(metagrad)* np.linalg.norm(old_metagrad[0]))) old_metagrad[0] = metagrad print "Meta Epoch {0} Train loss {1:2.4f} Valid Loss {2:2.4f}" \ " Test Loss {3:2.4f} Test Err {4:2.4f}".format( i_hyper, meta_results['train_loss'][-1], meta_results['valid_loss'][-1], meta_results['tests_loss'][-1], meta_results['test_err'][-1]) final_result = adam(hyperloss_grad, hyperparams.vect, meta_callback, N_meta_iter, meta_alpha) meta_callback(final_result, N_meta_iter) parser.vect = None # No need to pickle zeros return meta_results, parser
if metagrad is not None: meta_results['meta_grad_magnitude'].append(np.linalg.norm(metagrad)) meta_results['meta_grad_angle'].append(np.dot(old_metagrad[0], metagrad) \ / (np.linalg.norm(metagrad)* np.linalg.norm(old_metagrad[0]))) old_metagrad[0] = metagrad print "Meta Epoch {0} Train loss {1:2.4f} Valid Loss {2:2.4f}" \ " Test Loss {3:2.4f} Test Err {4:2.4f}".format( i_hyper, meta_results['train_loss'][-1], meta_results['valid_loss'][-1], meta_results['train_loss'][-1], meta_results['test_err'][-1]) initial_hypergrad = hyperloss_grad(hyperparams.vect, 0) parsed_init_hypergrad = hyperparams.new_vect(initial_hypergrad.copy()) final_result = adam(hyperloss_grad, hyperparams.vect, meta_callback, N_meta_iter, meta_alpha) meta_callback(final_result, N_meta_iter) parser.vect = None # No need to pickle zeros results = (meta_results, parser, parsed_init_hypergrad) pickle.dump(results, open('results.pkl', 'w')) # -- # Plot results, parser, parsed_init_hypergrad = pickle.load(open('bak/results.pkl')) fig = plt.figure(0) fig.clf() ax = fig.add_subplot(111) def layer_name(weight_key):
def run(): train_data, valid_data, tests_data = load_data_dicts( N_train, N_valid, N_tests) parser, pred_fun, loss_fun, frac_err = make_nn_funs(layer_sizes) N_weight_types = len(parser.names) hyperparams = VectorParser() hyperparams['log_L2_reg'] = np.full(N_weight_types, init_log_L2_reg) hyperparams['log_param_scale'] = np.full(N_weight_types, init_log_param_scale) hyperparams['log_alphas'] = np.full(N_iters, init_log_alphas) hyperparams['invlogit_betas'] = np.full(N_iters, init_invlogit_betas) fixed_hyperparams = VectorParser() fixed_hyperparams['log_param_scale'] = np.full(N_iters, init_log_param_scale) # TODO: memoize def primal_optimizer(hyperparam_vect, i_hyper): def indexed_loss_fun(w, L2_vect, i_iter): rs = npr.RandomState( npr.RandomState(global_seed + i_hyper + i_iter * 10000).randint(1000)) seed = i_hyper * 10**6 + i_iter # Deterministic seed needed for backwards pass. idxs = rs.randint(N_train, size=batch_size) return loss_fun(w, train_data['X'][idxs], train_data['T'][idxs], L2_vect) learning_curve_dict = defaultdict(list) def callback(x, v, g, i_iter): if i_iter % thin == 0: learning_curve_dict['learning_curve'].append( loss_fun(x, **train_data)) learning_curve_dict['grad_norm'].append(np.linalg.norm(g)) learning_curve_dict['weight_norm'].append(np.linalg.norm(x)) learning_curve_dict['velocity_norm'].append(np.linalg.norm(v)) cur_hyperparams = hyperparams.new_vect(hyperparam_vect) W0 = fill_parser(parser, np.exp(fixed_hyperparams['log_param_scale'])) W0 *= npr.RandomState(global_seed + i_hyper).randn(W0.size) alphas = np.exp(cur_hyperparams['log_alphas']) betas = logit(cur_hyperparams['invlogit_betas']) L2_reg = fill_parser(parser, np.exp(cur_hyperparams['log_L2_reg'])) W_opt = sgd4(grad(indexed_loss_fun), kylist(W0, alphas, betas, L2_reg), callback) #callback(W_opt, N_iters) return W_opt, learning_curve_dict def hyperloss(hyperparam_vect, i_hyper): W_opt, _ = primal_optimizer(hyperparam_vect, i_hyper) return loss_fun(W_opt, **valid_data) hyperloss_grad = grad(hyperloss) meta_results = defaultdict(list) old_metagrad = [np.ones(hyperparams.vect.size)] def meta_callback(hyperparam_vect, i_hyper, metagrad): x, learning_curve_dict = primal_optimizer(hyperparam_vect, i_hyper) cur_hyperparams = hyperparams.new_vect(hyperparam_vect.copy()) for field in cur_hyperparams.names: meta_results[field].append(cur_hyperparams[field]) meta_results['train_loss'].append(loss_fun(x, **train_data)) meta_results['valid_loss'].append(loss_fun(x, **valid_data)) meta_results['tests_loss'].append(loss_fun(x, **tests_data)) meta_results['test_err'].append(frac_err(x, **tests_data)) meta_results['learning_curves'].append(learning_curve_dict) meta_results['meta_grad_magnitude'].append(np.linalg.norm(metagrad)) meta_results['meta_grad_angle'].append(np.dot(old_metagrad[0], metagrad) \ / (np.linalg.norm(metagrad)* np.linalg.norm(old_metagrad[0]))) old_metagrad[0] = metagrad print "Meta Epoch {0} Train loss {1:2.4f} Valid Loss {2:2.4f}" \ " Test Loss {3:2.4f} Test Err {4:2.4f}".format( i_hyper, meta_results['train_loss'][-1], meta_results['valid_loss'][-1], meta_results['tests_loss'][-1], meta_results['test_err'][-1]) #Michael: train->tests final_result = adam(hyperloss_grad, hyperparams.vect, meta_callback, N_meta_iter, meta_alpha) #meta_callback(final_result, N_meta_iter) parser.vect = None # No need to pickle zeros return meta_results, parser
def run(): train_data, valid_data, tests_data = load_data_dicts( N_train, N_valid, N_tests) parser, pred_fun, loss_fun, frac_err = make_nn_funs(layer_sizes) N_weight_types = len(parser.names) rs = RandomState((seed)) init_fake_data = rs.randn(*(train_data['X'].shape)) * init_fake_data_scale one_hot = lambda x, K: np.array(x[:, None] == np.arange(K)[None, :], dtype=int) fake_labels = one_hot(np.array(range(N_train)) % N_classes, N_classes) # One of each. hyperparams = VectorParser() hyperparams['fake_data'] = init_fake_data fixed_hyperparams = VectorParser() fixed_hyperparams['log_param_scale'] = np.full(N_weight_types, init_log_param_scale) fixed_hyperparams['log_alphas'] = np.full((N_iters, N_weight_types), init_log_alphas) fixed_hyperparams['invlogit_betas'] = np.full((N_iters, N_weight_types), init_invlogit_betas) fixed_hyperparams['log_L2_reg'] = np.full(N_weight_types, init_log_L2_reg) cur_primal_results = {} loss_meta_parser = VectorParser() loss_meta_parser[''] def primal_optimizer(hyperparam_vect, i_hyper): def indexed_loss_fun(w, meta_vect, i_iter): (train_data, train_labels, L2_vect) = meta return loss_fun(w, train_data, train_labels, L2_vect) #return loss_fun(w, train_data['X'], train_data['T'], L2_vect + np.sum(fake_data.ravel())) learning_curve_dict = defaultdict(list) def callback(x, v, g, i_iter): if i_iter % thin == 0: # learning_curve_dict['learning_curve'].append(loss_fun(x, getval(cur_hyperparams['fake_data']), fake_labels)) learning_curve_dict['grad_norm'].append(np.linalg.norm(g)) learning_curve_dict['weight_norm'].append(np.linalg.norm(x)) learning_curve_dict['velocity_norm'].append(np.linalg.norm(v)) cur_hyperparams = hyperparams.new_vect(hyperparam_vect) fake_data = cur_hyperparams['fake_data'] rs = RandomState((seed, i_hyper)) W0 = fill_parser(parser, np.exp(fixed_hyperparams['log_param_scale'])) W0 *= rs.randn(W0.size) alphas = np.exp(fixed_hyperparams['log_alphas']) betas = logit(fixed_hyperparams['invlogit_betas']) L2_reg = fill_parser(parser, np.exp(fixed_hyperparams['log_L2_reg'])) meta = kylist(fake_data, fake_labels, L2_reg) W_opt = sgd_parsed(grad(indexed_loss_fun), kylist(W0, alphas, betas, meta), parser, callback=callback) cur_primal_results['weights'] = getval(W_opt).copy() cur_primal_results['learning_curve'] = getval(learning_curve_dict) return W_opt, learning_curve_dict def hyperloss(hyperparam_vect, i_hyper): W_opt, _ = primal_optimizer(hyperparam_vect, i_hyper) return loss_fun(W_opt, **valid_data) hyperloss_grad = grad(hyperloss) meta_results = defaultdict(list) old_metagrad = [np.ones(hyperparams.vect.size)] def meta_callback(hyperparam_vect, i_hyper, metagrad=None): x, learning_curve_dict = cur_primal_results[ 'weights'], cur_primal_results['learning_curve'] cur_hyperparams = hyperparams.new_vect(hyperparam_vect.copy()) for field in cur_hyperparams.names: meta_results[field].append(cur_hyperparams[field]) #meta_results['train_loss'].append(loss_fun(x, getval(cur_hyperparams['fake_data']), fake_labels)) meta_results['train_loss'].append(0) meta_results['valid_loss'].append(loss_fun(x, **valid_data)) meta_results['tests_loss'].append(loss_fun(x, **tests_data)) meta_results['test_err'].append(frac_err(x, **tests_data)) meta_results['learning_curves'].append(learning_curve_dict) meta_results['example_weights'] = x if metagrad is not None: print metagrad meta_results['meta_grad_magnitude'].append( np.linalg.norm(metagrad)) meta_results['meta_grad_angle'].append(np.dot(old_metagrad[0], metagrad) \ / (np.linalg.norm(metagrad)* np.linalg.norm(old_metagrad[0]))) old_metagrad[0] = metagrad print "Meta Epoch {0} Train loss {1:2.4f} Valid Loss {2:2.4f}" \ " Test Loss {3:2.4f} Test Err {4:2.4f}".format( i_hyper, meta_results['train_loss'][-1], meta_results['valid_loss'][-1], meta_results['tests_loss'][-1], meta_results['test_err'][-1]) final_result = adam(hyperloss_grad, hyperparams.vect, meta_callback, N_meta_iter, meta_alpha) meta_callback(final_result, N_meta_iter) parser.vect = None # No need to pickle zeros return meta_results, parser