def main(): global args, optimizer_select # To set the model name automatically print args lr = args.lr args = get_model_name(args) print 'Model name: {}'.format(args.model_name) # To set the random seed random.seed(args.seed) torch.manual_seed(args.seed + 1) torch.cuda.manual_seed(args.seed + 2) print("Loading training set and testing set..."), train_set = visual_genome(args.dataset_option, 'train') test_set = visual_genome('small', 'test') print("Done.") train_loader = torch.utils.data.DataLoader(train_set, batch_size=1, shuffle=True, num_workers=8, pin_memory=True) test_loader = torch.utils.data.DataLoader(test_set, batch_size=1, shuffle=False, num_workers=8, pin_memory=True) # Model declaration net = Hierarchical_Descriptive_Model( nhidden=args.mps_feature_len, n_object_cats=train_set.num_object_classes, n_predicate_cats=train_set.num_predicate_classes, n_vocab=train_set.voc_size, voc_sign=train_set.voc_sign, max_word_length=train_set.max_size, MPS_iter=args.MPS_iter, use_language_loss=not args.disable_language_model, object_loss_weight=train_set.inverse_weight_object, predicate_loss_weight=train_set.inverse_weight_predicate, dropout=args.dropout, use_kmeans_anchors=not args.use_normal_anchors, gate_width=args.gate_width, nhidden_caption=args.nhidden_caption, nembedding=args.nembedding, rnn_type=args.rnn_type, rnn_droptout=args.caption_use_dropout, rnn_bias=args.caption_use_bias, use_region_reg=args.region_bbox_reg, use_kernel=args.use_kernel_function) params = list(net.parameters()) for param in params: print param.size() print net # To group up the features vgg_features_fix, vgg_features_var, rpn_features, hdn_features, language_features = group_features( net) # Setting the state of the training model net.cuda() net.train() logger_path = "log/logger/{}".format(args.model_name) if os.path.exists(logger_path): shutil.rmtree(logger_path) configure(logger_path, flush_secs=5) # setting up the logger network.set_trainable(net, False) # network.weights_normal_init(net, dev=0.01) if args.finetune_language_model: print 'Only finetuning the language model from: {}'.format( args.resume_model) args.train_all = False if len(args.resume_model) == 0: raise Exception('[resume_model] not specified') network.load_net(args.resume_model, net) optimizer_select = 3 elif args.load_RPN: print 'Loading pretrained RPN: {}'.format(args.saved_model_path) args.train_all = False network.load_net(args.saved_model_path, net.rpn) net.reinitialize_fc_layers() optimizer_select = 1 elif args.resume_training: print 'Resume training from: {}'.format(args.resume_model) if len(args.resume_model) == 0: raise Exception('[resume_model] not specified') network.load_net(args.resume_model, net) args.train_all = True optimizer_select = 2 else: print 'Training from scratch.' net.rpn.initialize_parameters() net.reinitialize_fc_layers() optimizer_select = 0 args.train_all = True optimizer = network.get_optimizer(lr, optimizer_select, args, vgg_features_var, rpn_features, hdn_features, language_features) target_net = net if not os.path.exists(args.output_dir): os.mkdir(args.output_dir) top_Ns = [50, 100] best_recall = np.zeros(len(top_Ns)) if args.evaluate: recall = test(test_loader, net, top_Ns) print('======= Testing Result =======') for idx, top_N in enumerate(top_Ns): print( '[Recall@{top_N:d}] {recall:2.3f}%% (best: {best_recall:2.3f}%%)' .format(top_N=top_N, recall=recall[idx] * 100, best_recall=best_recall[idx] * 100)) print('==============================') else: for epoch in range(0, args.max_epoch): # Training train(train_loader, target_net, optimizer, epoch) # snapshot the state save_name = os.path.join( args.output_dir, '{}_epoch_{}.h5'.format(args.model_name, epoch)) network.save_net(save_name, net) print('save model: {}'.format(save_name)) # Testing # network.set_trainable(net, False) # Without backward(), requires_grad takes no effect recall = test(test_loader, net, top_Ns) if np.all(recall > best_recall): best_recall = recall save_name = os.path.join(args.output_dir, '{}_best.h5'.format(args.model_name)) network.save_net(save_name, net) print('\nsave model: {}'.format(save_name)) print('Epoch[{epoch:d}]:'.format(epoch=epoch)), for idx, top_N in enumerate(top_Ns): print( '\t[Recall@{top_N:d}] {recall:2.3f}%% (best: {best_recall:2.3f}%%)' .format(top_N=top_N, recall=recall[idx] * 100, best_recall=best_recall[idx] * 100)), # updating learning policy if epoch % args.step_size == 0 and epoch > 0: lr /= 10 args.lr = lr print '[learning rate: {}]'.format(lr) args.enable_clip_gradient = False if not args.finetune_language_model: args.train_all = True optimizer_select = 2 # update optimizer and correponding requires_grad state optimizer = network.get_optimizer(lr, optimizer_select, args, vgg_features_var, rpn_features, hdn_features, language_features)
def main(): global args, optimizer_select # To set the model name automatically print args lr = args.lr args = get_model_name(args) print 'Model name: {}'.format(args.model_name) # To set the random seed random.seed(args.seed) torch.manual_seed(args.seed + 1) torch.cuda.manual_seed(args.seed + 2) # print("Loading training set and testing set..."), # train_set = visual_genome(args.dataset_option, 'train') # test_set = visual_genome('small', 'test') # print("Done.") # train_loader = torch.utils.data.DataLoader(train_set, batch_size=1, shuffle=True, num_workers=8, pin_memory=True) # test_loader = torch.utils.data.DataLoader(test_set, batch_size=1, shuffle=False, num_workers=8, pin_memory=True) image_set = prepare_image(datapath=args.total_image_path) image_loader = torch.utils.data.DataLoader(image_set, batch_size=1, shuffle=False, num_workers=8, pin_memory=True) # Model declaration net = Hierarchical_Descriptive_Model( nhidden=args.mps_feature_len, n_object_cats=5, n_predicate_cats=5, n_vocab=5, voc_sign=5, max_word_length=5, MPS_iter=args.MPS_iter, use_language_loss=not args.disable_language_model, object_loss_weight=5, predicate_loss_weight=5, dropout=args.dropout, use_kmeans_anchors=not args.use_normal_anchors, gate_width=args.gate_width, nhidden_caption=args.nhidden_caption, nembedding=args.nembedding, rnn_type=args.rnn_type, rnn_droptout=args.caption_use_dropout, rnn_bias=args.caption_use_bias, use_region_reg=args.region_bbox_reg, use_kernel=args.use_kernel_function) params = list(net.parameters()) for param in params: print param.size() print net # To group up the features vgg_features_fix, vgg_features_var, rpn_features, hdn_features, language_features = group_features( net) # Setting the state of the training model net.cuda() net.train() logger_path = "log/logger/{}".format(args.model_name) if os.path.exists(logger_path): shutil.rmtree(logger_path) configure(logger_path, flush_secs=5) # setting up the logger network.set_trainable(net, False) # network.weights_normal_init(net, dev=0.01) if args.finetune_language_model: print 'Only finetuning the language model from: {}'.format( args.resume_model) args.train_all = False if len(args.resume_model) == 0: raise Exception('[resume_model] not specified') network.load_net(args.resume_model, net) optimizer_select = 3 elif args.load_RPN: print 'Loading pretrained RPN: {}'.format(args.saved_model_path) args.train_all = False network.load_net(args.saved_model_path, net.rpn) net.reinitialize_fc_layers() optimizer_select = 1 elif args.resume_training: print 'Resume training from: {}'.format(args.resume_model) if len(args.resume_model) == 0: raise Exception('[resume_model] not specified') network.load_net(args.resume_model, net) args.train_all = True optimizer_select = 2 else: print 'Training from scratch.' net.rpn.initialize_parameters() net.reinitialize_fc_layers() optimizer_select = 0 args.train_all = True optimizer = network.get_optimizer(lr, optimizer_select, args, vgg_features_var, rpn_features, hdn_features, language_features) target_net = net if not os.path.exists(args.output_dir): os.mkdir(args.output_dir) top_Ns = [50, 100] best_recall = np.zeros(len(top_Ns)) extract_features(image_loader, net)
def main(): global args, optimizer_select # To set the model name automatically print args lr = args.lr args = get_model_name(args) print 'Model name: {}'.format(args.model_name) # To set the random seed random.seed(args.seed) torch.manual_seed(args.seed + 1) torch.cuda.manual_seed(args.seed + 2) print("Loading training set and testing set...") train_set = visual_genome(args.dataset_option, 'train') test_set = visual_genome(args.dataset_option, 'test') print("Done.") train_loader = torch.utils.data.DataLoader(train_set, batch_size=1, shuffle=True, num_workers=8, pin_memory=True) test_loader = torch.utils.data.DataLoader(test_set, batch_size=1, shuffle=True, num_workers=8, pin_memory=True) net = Hierarchical_Descriptive_Model( nhidden=args.mps_feature_len, n_object_cats=train_set.num_object_classes, n_predicate_cats=train_set.num_predicate_classes, MPS_iter=args.MPS_iter, object_loss_weight=train_set.inverse_weight_object, predicate_loss_weight=train_set.inverse_weight_predicate, dropout=args.dropout, use_kmeans_anchors=args.use_kmeans_anchors, base_model=args.base_model) #True # params = list(net.parameters()) # for param in params: # print param.size() print net # Setting the state of the training model net.cuda() net.train() network.set_trainable(net, False) # network.weights_normal_init(net, dev=0.01) if args.resume_model: print 'Resume training from: {}'.format(args.HDN_model) if len(args.HDN_model) == 0: raise Exception('[resume_model] not specified') network.load_net(args.HDN_model, net) # network.load_net(args.RPN_model, net.rpn) args.train_all = True optimizer_select = 3 elif args.load_RCNN: print 'Loading pretrained RCNN: {}'.format(args.RCNN_model) args.train_all = False network.load_net(args.RCNN_model, net.rcnn) optimizer_select = 2 elif args.load_RPN: print 'Loading pretrained RPN: {}'.format(args.RPN_model) args.train_all = False network.load_net(args.RPN_model, net.rpn) net.reinitialize_fc_layers() optimizer_select = 1 else: print 'Training from scratch.' net.rpn.initialize_parameters() net.reinitialize_fc_layers() optimizer_select = 0 args.train_all = True # To group up the features # vgg_features_fix, vgg_features_var, rpn_features, hdn_features = group_features(net) basenet_features, rpn_features, rcnn_feature, hdn_features = group_features( net) optimizer = network.get_optimizer(lr, optimizer_select, args, basenet_features, rpn_features, rcnn_feature, hdn_features) target_net = net if not os.path.exists(args.output_dir): os.mkdir(args.output_dir) top_Ns = [50, 100] best_recall = np.zeros(len(top_Ns)) if args.evaluate: recall = test(test_loader, target_net, top_Ns, train_set.object_classes) print('======= Testing Result =======') for idx, top_N in enumerate(top_Ns): print( '[Recall@{top_N:d}] {recall:2.3f}%% (best: {best_recall:2.3f}%%)' .format(top_N=top_N, recall=recall[idx] * 100, best_recall=best_recall[idx] * 100)) print('==============================') else: for epoch in range(0, args.max_epoch): # Training train(train_loader, target_net, optimizer, epoch) # snapshot the state save_name = os.path.join( args.output_dir, '{}_epoch_{}.h5'.format(args.model_name, epoch)) network.save_net(save_name, net) print('save model: {}'.format(save_name)) recall = test(test_loader, target_net, top_Ns, train_set.object_classes) if np.all(recall > best_recall): best_recall = recall save_name = os.path.join(args.output_dir, '{}_best.h5'.format(args.model_name)) network.save_net(save_name, net) print('\nsave model: {}'.format(save_name)) print('Epoch[{epoch:d}]:'.format(epoch=epoch)), for idx, top_N in enumerate(top_Ns): print( '\t[Recall@{top_N:d}] {recall:2.3f}%% (best: {best_recall:2.3f}%%)' .format(top_N=top_N, recall=recall[idx] * 100, best_recall=best_recall[idx] * 100)) # updating learning policy if (epoch + 1) % args.step_size == 0 or (epoch + 1) % ( args.step_size + 2) == 0: lr /= 10 args.lr = lr print '[learning rate: {}]'.format(lr) args.enable_clip_gradient = False args.train_all = False optimizer_select = 2 # update optimizer and correponding requires_grad state optimizer = network.get_optimizer(lr, optimizer_select, args, basenet_features, rpn_features, rcnn_feature, hdn_features)
def __init__(self): # To set the model name automatically args = parser.parse_args() print args args = get_model_name(args) print 'Model name: {}'.format(args.model_name) self.check = True # To set the random seed random.seed(args.seed) torch.manual_seed(args.seed + 1) torch.cuda.manual_seed(args.seed + 2) print("Loading training params"), self.train_set = visual_genome('normal', 'train') print("Done.") self.train_loader = torch.utils.data.DataLoader(self.train_set, batch_size=1, shuffle=True, num_workers=8, pin_memory=True) end = time.time() # Model declaration self.net = Hierarchical_Descriptive_Model( nhidden=args.mps_feature_len, n_object_cats=self.train_set.num_object_classes, n_predicate_cats=self.train_set.num_predicate_classes, n_vocab=self.train_set.voc_size, voc_sign=self.train_set.voc_sign, max_word_length=self.train_set.max_size, MPS_iter=args.MPS_iter, use_language_loss=not args.disable_language_model, object_loss_weight=self.train_set.inverse_weight_object, predicate_loss_weight=self.train_set.inverse_weight_predicate, dropout=args.dropout, use_kmeans_anchors=not args.use_normal_anchors, gate_width=args.gate_width, nhidden_caption=args.nhidden_caption, nembedding=args.nembedding, rnn_type=args.rnn_type, rnn_droptout=args.caption_use_dropout, rnn_bias=args.caption_use_bias, use_region_reg=args.region_bbox_reg, use_kernel=args.use_kernel_function) params = list(self.net.parameters()) for param in params: print param.size() print self.net # To group up the features vgg_features_fix, vgg_features_var, rpn_features, hdn_features, language_features = group_features( self.net) # Setting the state of the training model self.net.cuda() self.net.train() network.set_trainable(self.net, False) # loading model for inference print 'Resume training from: {}'.format(args.resume_model) if len(args.resume_model) == 0: raise Exception('[resume_model] not specified') network.load_net(args.resume_model, self.net) args.train_all = True optimizer_select = 2 optimizer = network.get_optimizer(args.lr, optimizer_select, args, vgg_features_var, rpn_features, hdn_features, language_features) target_net = self.net self.net.eval() print('Model Loading time: ', time.time() - end) # Set topics self.bridge = CvBridge() self.dot = Digraph(comment='warehouse', format='svg') self.regions_dot = Digraph(comment='regions', format='svg') self.image_sub = message_filters.Subscriber( '/turtlebot2i/camera/rgb/raw_image', Image) self.image_depth_sub = message_filters.Subscriber( '/turtlebot2i/camera/depth/raw_image', Image) self.ts = message_filters.TimeSynchronizer( [self.image_sub, self.image_depth_sub], queue_size=1) print('calling callback') self.ts.registerCallback(self.callback) self.scenegraph_pub = rospy.Publisher('/turtlebot2i/scene_graph', SceneGraph, queue_size=10)