def main():
args = parser.parse_args()
print('Options:')
for (key, value) in vars(args).iteritems():
print("{:16}: {}".format(key, value))
assert os.path.exists(args.xp_dir)
# default value for basefile: string basis for all exported file names
if args.out_name:
base_file = "{}/{}".format(args.xp_dir, args.out_name)
else:
base_file = "{}/{}_{}_{}".format(args.xp_dir, args.dataset,
args.solver, args.loss)
# if pickle file already there, consider run already done
if (os.path.exists("{}_weights.p".format(base_file))
and os.path.exists("{}_results.p".format(base_file))):
sys.exit()
# computation device
if 'gpu' in args.device:
theano.sandbox.cuda.use(args.device)
# set save_at to n_epochs if not provided
save_at = args.n_epochs if not args.save_at else args.save_at
save_to = "{}_weights.p".format(base_file)
weights = "../log/{}.p".format(args.in_name) if args.in_name else None
# update config data
# plot parameters
Cfg.xp_path = args.xp_dir
# dataset
Cfg.seed = args.seed
Cfg.out_frac = args.out_frac
Cfg.ad_experiment = bool(args.ad_experiment)
Cfg.weight_dict_init = bool(args.weight_dict_init)
Cfg.pca = bool(args.pca)
Cfg.unit_norm_used = args.unit_norm_used
Cfg.gcn = bool(args.gcn)
Cfg.zca_whitening = bool(args.zca_whitening)
Cfg.mnist_val_frac = args.mnist_val_frac
Cfg.mnist_bias = bool(args.mnist_bias)
Cfg.mnist_rep_dim = args.mnist_rep_dim
Cfg.mnist_architecture = args.mnist_architecture
Cfg.mnist_normal = args.mnist_normal
Cfg.mnist_outlier = args.mnist_outlier
Cfg.cifar10_bias = bool(args.cifar10_bias)
Cfg.cifar10_rep_dim = args.cifar10_rep_dim
Cfg.cifar10_architecture = args.cifar10_architecture
Cfg.cifar10_normal = args.cifar10_normal
Cfg.cifar10_outlier = args.cifar10_outlier
Cfg.gtsrb_rep_dim = args.gtsrb_rep_dim
# neural network
Cfg.softmax_loss = (args.loss == 'ce')
Cfg.svdd_loss = (args.loss == 'svdd')
Cfg.kde_loss = (args.loss == 'kde_loss')
Cfg.deep_GMM_loss = (args.loss == 'deep_GMM')
Cfg.reconstruction_loss = (args.loss == 'autoencoder')
Cfg.use_batch_norm = bool(args.use_batch_norm)
Cfg.learning_rate.set_value(args.lr)
Cfg.lr_decay = bool(args.lr_decay)
Cfg.lr_decay_after_epoch = args.lr_decay_after_epoch
Cfg.lr_drop = bool(args.lr_drop)
Cfg.lr_drop_in_epoch = args.lr_drop_in_epoch
Cfg.lr_drop_factor = args.lr_drop_factor
Cfg.momentum.set_value(args.momentum)
if args.solver == "rmsprop":
Cfg.rho.set_value(0.9)
if args.solver == "adadelta":
Cfg.rho.set_value(0.95)
Cfg.block_coordinate = bool(args.block_coordinate)
Cfg.k_update_epochs = args.k_update_epochs
Cfg.center_fixed = bool(args.center_fixed)
Cfg.R_update_solver = args.R_update_solver
Cfg.R_update_scalar_method = args.R_update_scalar_method
Cfg.R_update_lp_obj = args.R_update_lp_obj
Cfg.warm_up_n_epochs = args.warm_up_n_epochs
Cfg.batch_size = args.batch_size
Cfg.leaky_relu = bool(args.leaky_relu)
# Pre-training and autoencoder configuration
Cfg.pretrain = bool(args.pretrain)
Cfg.ae_loss = args.ae_loss
Cfg.ae_lr_drop = bool(args.ae_lr_drop)
Cfg.ae_lr_drop_in_epoch = args.ae_lr_drop_in_epoch
Cfg.ae_lr_drop_factor = args.ae_lr_drop_factor
Cfg.ae_weight_decay = bool(args.ae_weight_decay)
Cfg.ae_C.set_value(args.ae_C)
# SVDD parameters
Cfg.nu.set_value(args.nu)
Cfg.c_mean_init = bool(args.c_mean_init)
if args.c_mean_init_n_batches == -1:
Cfg.c_mean_init_n_batches = "all"
else:
Cfg.c_mean_init_n_batches = args.c_mean_init_n_batches
Cfg.hard_margin = bool(args.hard_margin)
# regularization
Cfg.weight_decay = bool(args.weight_decay)
Cfg.C.set_value(args.C)
Cfg.reconstruction_penalty = bool(args.reconstruction_penalty)
Cfg.C_rec.set_value(args.C_rec)
Cfg.dropout = bool(args.dropout)
Cfg.dropout_architecture = bool(args.dropout_arch)
# diagnostics
Cfg.nnet_diagnostics = bool(args.nnet_diagnostics)
Cfg.e1_diagnostics = bool(args.e1_diagnostics)
Cfg.ae_diagnostics = bool(args.ae_diagnostics)
# train
nnet = NeuralNet(dataset=args.dataset,
use_weights=weights,
pretrain=Cfg.pretrain)
# pre-train weights via autoencoder, if specified
if Cfg.pretrain:
nnet.pretrain(solver="adam", lr=0.0001, n_epochs=1)
nnet.train(solver=args.solver,
n_epochs=args.n_epochs,
save_at=save_at,
save_to=save_to)
# pickle/serialize AD results
if Cfg.ad_experiment:
nnet.log_results(filename=Cfg.xp_path + "/AD_results.p")
# text log
nnet.log.save_to_file("{}_results.p".format(base_file)) # save log
log_exp_config(Cfg.xp_path, args.dataset)
log_NeuralNet(Cfg.xp_path, args.loss, args.solver, args.lr, args.momentum,
None, args.n_epochs, args.C, args.C_rec, args.nu)
if Cfg.ad_experiment:
log_AD_results(Cfg.xp_path, nnet)
# plot diagnostics
if Cfg.nnet_diagnostics:
# common suffix for plot titles
str_lr = "lr = " + str(args.lr)
C = int(args.C)
if not Cfg.weight_decay:
C = None
str_C = "C = " + str(C)
Cfg.title_suffix = "(" + args.solver + ", " + str_C + ", " + str_lr + ")"
if args.loss == 'autoencoder':
plot_ae_diagnostics(nnet, Cfg.xp_path, Cfg.title_suffix)
else:
plot_diagnostics(nnet, Cfg.xp_path, Cfg.title_suffix)
plot_filters(nnet, Cfg.xp_path, Cfg.title_suffix)
# If AD experiment, plot most anomalous and most normal
if Cfg.ad_experiment:
n_img = 32
plot_outliers_and_most_normal(nnet, n_img, Cfg.xp_path)
def main():
args = parser.parse_args()
if Cfg.print_options:
print('Options:')
for (key, value) in vars(args).iteritems():
print("{:16}: {}".format(key, value))
assert os.path.exists(args.xp_dir)
# default value for basefile: string basis for all exported file names
if args.out_name:
base_file = "{}/{}".format(args.xp_dir, args.out_name)
else:
base_file = "{}/{}_{}_{}".format(args.xp_dir, args.dataset,
args.solver, args.loss)
# if pickle file already there, consider run already done
if not Cfg.only_test and (os.path.exists("{}_weights.p".format(base_file))
and os.path.exists(
"{}_results.p".format(base_file))):
sys.exit()
# computation device
# if 'gpu' in args.device:
# theano.sandbox.cuda.use(args.device)
# set save_at to n_epochs if not provided
save_at = args.n_epochs if not args.save_at else args.save_at
save_to = "{}_weights.p".format(base_file)
weights = "{}/{}.p".format(args.xp_dir,
args.in_name) if args.in_name else None
print(weights)
# update config data
# plot parameters
Cfg.xp_path = args.xp_dir
# dataset
Cfg.seed = args.seed
Cfg.out_frac = args.out_frac
Cfg.ad_experiment = bool(args.ad_experiment)
Cfg.weight_dict_init = bool(args.weight_dict_init)
Cfg.pca = bool(args.pca)
Cfg.unit_norm_used = args.unit_norm_used
Cfg.gcn = bool(args.gcn)
Cfg.zca_whitening = bool(args.zca_whitening)
Cfg.mnist_val_frac = args.mnist_val_frac
Cfg.mnist_bias = bool(args.mnist_bias)
Cfg.mnist_rep_dim = args.mnist_rep_dim
Cfg.mnist_architecture = args.mnist_architecture
Cfg.mnist_normal = args.mnist_normal
Cfg.mnist_outlier = args.mnist_outlier
Cfg.cifar10_bias = bool(args.cifar10_bias)
Cfg.cifar10_rep_dim = args.cifar10_rep_dim
Cfg.cifar10_architecture = args.cifar10_architecture
Cfg.cifar10_normal = args.cifar10_normal
Cfg.cifar10_outlier = args.cifar10_outlier
Cfg.gtsrb_rep_dim = args.gtsrb_rep_dim
# Cfg.bdd100k_rep_dim = args.bdd100k_rep_dim
# Cfg.bdd100k_architecture = args.bdd100k_architecture
# Cfg.bdd100k_val_frac = args.bdd100k_val_frac
# Cfg.bdd100k_bias = args.bdd100k_bias
# Cfg.bdd100k_n_train = args.bdd100k_n_train
# Cfg.bdd100k_n_test = args.bdd100k_n_test
# neural network
Cfg.softmax_loss = (args.loss == 'ce')
Cfg.svdd_loss = (args.loss == 'svdd')
Cfg.reconstruction_loss = (args.loss == 'autoencoder')
Cfg.use_batch_norm = bool(args.use_batch_norm)
Cfg.learning_rate.set_value(args.lr)
Cfg.lr_decay = bool(args.lr_decay)
Cfg.lr_decay_after_epoch = args.lr_decay_after_epoch
Cfg.lr_drop = bool(args.lr_drop)
Cfg.lr_drop_in_epoch = args.lr_drop_in_epoch
Cfg.lr_drop_factor = args.lr_drop_factor
Cfg.momentum.set_value(args.momentum)
if args.solver == "rmsprop":
Cfg.rho.set_value(0.9)
if args.solver == "adadelta":
Cfg.rho.set_value(0.95)
Cfg.block_coordinate = bool(args.block_coordinate)
Cfg.k_update_epochs = args.k_update_epochs
Cfg.center_fixed = bool(args.center_fixed)
Cfg.R_update_solver = args.R_update_solver
Cfg.R_update_scalar_method = args.R_update_scalar_method
Cfg.R_update_lp_obj = args.R_update_lp_obj
Cfg.warm_up_n_epochs = args.warm_up_n_epochs
Cfg.batch_size = args.batch_size
Cfg.leaky_relu = bool(args.leaky_relu)
# Pre-training and autoencoder configuration
Cfg.pretrain = bool(args.pretrain)
Cfg.ae_loss = args.ae_loss
Cfg.ae_lr_drop = bool(args.ae_lr_drop)
Cfg.ae_lr_drop_in_epoch = args.ae_lr_drop_in_epoch
Cfg.ae_lr_drop_factor = args.ae_lr_drop_factor
Cfg.ae_weight_decay = bool(args.ae_weight_decay)
Cfg.ae_C.set_value(args.ae_C)
# SVDD parameters
Cfg.nu.set_value(args.nu)
Cfg.c_mean_init = bool(args.c_mean_init)
if args.c_mean_init_n_batches == -1:
Cfg.c_mean_init_n_batches = "all"
else:
Cfg.c_mean_init_n_batches = args.c_mean_init_n_batches
Cfg.hard_margin = bool(args.hard_margin)
# regularization
Cfg.weight_decay = bool(args.weight_decay)
Cfg.C.set_value(args.C)
Cfg.reconstruction_penalty = bool(args.reconstruction_penalty)
Cfg.C_rec.set_value(args.C_rec)
Cfg.dropout = bool(args.dropout)
Cfg.dropout_architecture = bool(args.dropout_arch)
# diagnostics
Cfg.nnet_diagnostics = bool(args.nnet_diagnostics)
Cfg.e1_diagnostics = bool(args.e1_diagnostics)
Cfg.ae_diagnostics = bool(args.ae_diagnostics)
# Check for previous copy of configuration and compare, abort if not equal
logged_config = args.xp_dir + "/configuration.py"
current_config = "./config.py"
if os.path.exists(logged_config):
print("Comparing logged and current config")
# assert(files_equal(logged_config,current_config, "dataset ="))
else:
copyfile(current_config, logged_config)
if not Cfg.only_test: # Run original DSVDD code, both training and testing in one
# train
# load from checkpoint if available
start_new_nnet = False
if os.path.exists(args.xp_dir + "/ae_pretrained_weights.p"):
print("Pretrained AE found")
Cfg.pretrain = False
nnet = NeuralNet(dataset=args.dataset,
use_weights=args.xp_dir +
"/ae_pretrained_weights.p",
pretrain=False)
elif Cfg.pretrain:
if os.path.exists(args.xp_dir + "/ae_checkpoint.p"):
print("AE checkpoint found, resuming training")
nnet = NeuralNet(dataset=args.dataset,
use_weights=args.xp_dir + "/ae_checkpoint.p",
pretrain=True)
else:
start_new_nnet = True
elif os.path.exists(args.xp_dir + "/checkpoint.p"):
print("DSVDD checkpoint found, resuming training")
nnet = NeuralNet(dataset=args.dataset,
use_weights=args.xp_dir + "/checkpoint.p",
pretrain=False)
else:
start_new_nnet = True
if start_new_nnet:
nnet = NeuralNet(dataset=args.dataset,
use_weights=weights,
pretrain=Cfg.pretrain)
# pre-train weights via autoencoder, if specified
if Cfg.pretrain:
nnet.pretrain(solver="adam",
lr=Cfg.pretrain_learning_rate,
n_epochs=Cfg.n_pretrain_epochs)
nnet.train(solver=args.solver,
n_epochs=args.n_epochs,
save_at=save_at,
save_to=save_to)
# pickle/serialize AD results
if Cfg.ad_experiment:
nnet.log_results(filename=Cfg.xp_path + "/AD_results.p")
# text log
nnet.log.save_to_file("{}_results.p".format(base_file)) # save log
log_exp_config(Cfg.xp_path, args.dataset)
log_NeuralNet(Cfg.xp_path, args.loss, args.solver, args.lr,
args.momentum, None, args.n_epochs, args.C, args.C_rec,
args.nu, args.dataset)
if Cfg.ad_experiment:
log_AD_results(Cfg.xp_path, nnet)
# plot diagnostics
if Cfg.nnet_diagnostics:
# common suffix for plot titles
str_lr = "lr = " + str(args.lr)
C = int(args.C)
if not Cfg.weight_decay:
C = None
str_C = "C = " + str(C)
Cfg.title_suffix = "(" + args.solver + ", " + str_C + ", " + str_lr + ")"
if args.loss == 'autoencoder':
plot_ae_diagnostics(nnet, Cfg.xp_path, Cfg.title_suffix)
else:
plot_diagnostics(nnet, Cfg.xp_path, Cfg.title_suffix)
if Cfg.plot_filters:
print("Plotting filters")
plot_filters(nnet, Cfg.xp_path, Cfg.title_suffix)
# If AD experiment, plot most anomalous and most normal
if Cfg.ad_experiment and Cfg.plot_most_out_and_norm:
n_img = 32
plot_outliers_and_most_normal(nnet, n_img, Cfg.xp_path)
else: # Load previous network and run only test
# Load parameters from previous training
ae_net = NeuralNet(dataset=args.dataset,
use_weights=args.xp_dir +
"/ae_pretrained_weights.p",
pretrain=True)
ae_net.ae_solver = args.solver.lower()
#ae_net.ae_learning_rate = args.lr
#ae_net.ae_n_epochs = args.n_epochs
# set learning rate
#lr_tmp = Cfg.learning_rate.get_value()
#Cfg.learning_rate.set_value(Cfg.floatX(lr))
ae_net.compile_autoencoder()
_, recon_errors = ae_performance(ae_net, 'test')
print("Computed reconstruction errors")
nnet = NeuralNet(dataset=args.dataset,
use_weights="{}/weights_best_ep.p".format(
args.xp_dir))
nnet.solver = args.solver.lower()
nnet.compile_updates()
# nnet.evaluate(solver = args.solver)
# nnet.test_time = time.time() - nnet.clock
# # pickle/serialize AD results
# if Cfg.ad_experiment:
# nnet.log_results(filename=Cfg.xp_path + "/AD_results.p")
# TODO retrieve labels and scores from evaluation
_, _, dsvdd_scores = performance(nnet, 'test')
labels = nnet.data._y_test
# # text log
# nnet.log.save_to_file("{}_results.p".format(base_file)) # save log
# log_exp_config(Cfg.xp_path, args.dataset)
# log_NeuralNet(Cfg.xp_path, args.loss, args.solver, args.lr, args.momentum, None, args.n_epochs, args.C, args.C_rec,
# args.nu, args.dataset)
# if Cfg.ad_experiment:
# log_AD_results(Cfg.xp_path, nnet)
# Save scores and labels for comparison with other experiments
if Cfg.export_results:
for name in ("", "_recon_err"):
results_filepath = '/home/exjobb_resultat/data/%s_DSVDD%s.pkl' % (
args.dataset, name)
with open(results_filepath, 'wb') as f:
if name is "_recon_err":
pickle.dump([recon_errors, labels], f)
else:
pickle.dump([dsvdd_scores, labels], f)
print("Saved results to %s" % results_filepath)
# Update data source dict with experiment name
common_results_dict = pickle.load(
open('/home/exjobb_resultat/data/name_dict.pkl', 'rb'))
exp_name = args.xp_dir.strip('../log/%s/' % args.dataset)
common_results_dict[args.dataset]["DSVDD%s" % name] = exp_name
pickle.dump(
common_results_dict,
open('/home/exjobb_resultat/data/name_dict.pkl', 'wb'))
# print test results to console
print("\nOutliers from %s" % Cfg.test_out_folder)
print("%d inliers, %d outliers" %
(Cfg.n_test_in, Cfg.n_test - Cfg.n_test_in))
print("Test results:\n")
print("\t\tAUROC\tAUPRC\n")
# Compute test metrics before printing
auroc_recon = roc_auc_score(labels, recon_errors)
auroc_dsvdd = roc_auc_score(labels, dsvdd_scores)
pr, rc, _ = precision_recall_curve(labels, recon_errors)
auprc_recon = auc(rc, pr)
pr, rc, _ = precision_recall_curve(labels, dsvdd_scores)
auprc_dsvdd = auc(rc, pr)
print("Recon.err:\t%.4f\t%.4f" % (auroc_recon, auprc_recon))
print("DSVDD:\t\t%.4f\t%.4f" % (auroc_dsvdd, auprc_dsvdd))
