def train_step( input, ground_truth, model, train_fout=None, val_fout=None ): # training input and ground truth should already be synchronized and encoded # fout is there for if we want to record the loss data # get a validation input validation_input_name = np.random.choice(validation_files) # parse the validation set validation_input = loader.parse_input(validation_input_name, input_path) validation_label = sync.trim_front( loader.parse_label(validation_input_name, ground_truth_data_path)) val_input, val_label = sync.sync_data(validation_input, validation_label, len(validation_label)) val_label = np.array( loader.encode_multihot(val_label)) # encode to multi-hot val_input = np.array(val_input) val_input = np.reshape( val_input, (val_input.shape[0], 1, val_input.shape[1]) ) # reshape to a tensor which the neural net can use (batch_size, 1, samples_per_batch) with tf.GradientTape( ) as tape: # Start calculating the gradient and applying it # generate the predictions # it is garenteed the ground truth and prediction will have the same shape training_prediction = model(input) validation_prediction = model(val_input) training_losses = [ x(ground_truth, training_prediction) for x in loss_list ] # store all training losses validation_losses = [ x(val_label, validation_prediction) for x in loss_list ] # store all validation losses applicable_loss = training_losses[default_loss_index] visible_loss = validation_losses[default_loss_index] # store loss if (train_fout != None): write_loss(training_losses, loss_label, train_fout) if (val_fout != None): write_loss(validation_losses, loss_label, val_fout) # calculate and apply gradient grad = tape.gradient(applicable_loss, model.trainable_variables) # THIS SHIT DOESNT WORK AND IDK WHY default_opt.apply_gradients(zip(grad, model.trainable_variables)) overall_train_loss = np.mean(applicable_loss) overall_val_loss = np.mean(visible_loss) # CLI debug messages # print(colored('>>> Overall Training Loss: ', 'green') + colored(str(overall_train_loss), 'green', attrs=['bold', 'reverse'])) # print(colored('>>> Overall Validation Loss: ', 'green') + colored(str(overall_val_loss), 'green', attrs=['bold', 'reverse'])) return overall_train_loss, overall_val_loss
def train_step(input, label, model, train_fout=None, val_fout=None): # {X}_fout is there for if we want to record the loss data # get a validation input validation_input_name = np.random.choice(validation_files) # parse the validation set validation_input, val_sr = loader.parse_input( validation_input_name, input_path) # get input data and sample rate validation_label, val_bpm = loader.parse_label( validation_input_name, label_data_path) # get label data and bpm # generate mel spectrogram val_ml = loader.get_mel_spec(validation_input, mel_res, val_sr, window_size, hop_len) # trim the label data validation_label = sync.trim_front(validation_label) val_input, val_label = sync.sync_data(val_ml, validation_label, val_bpm, hop_len) val_label = np.array( loader.encode_multihot(val_label)) # encode to multi-hot val_input = np.reshape( val_input, (val_input.shape[0], val_input.shape[1], val_input.shape[2], 1)) # reshape to a tensor which the neural net can use (mini_batch_size, window_size, mel_resolution, channel) with tf.GradientTape( ) as tape: # Start calculating the gradient and applying it # generate the predictions # it is garenteed the ground truth and prediction will have the same shape training_prediction = [ ] # crate temporary array of predictions so we can concat them later for mini-batch processing for sample in input: temp_pred = model(sample) # get a training pred training_prediction.append(temp_pred) # concatinate the perdictions training_prediction = tf.concat(training_prediction, 0) validation_prediction = model(val_input) # get a validation pred training_losses = [x(label, training_prediction) for x in loss_list] # store all training losses validation_losses = [ x(val_label, validation_prediction) for x in loss_list ] # store all validation losses applicable_loss = training_losses[ default_loss_index] # idk why i named it this but this is the training loss visible_loss = validation_losses[default_loss_index] # validation loss # store loss if (train_fout != None): write_loss(training_losses, loss_label, train_fout) if (val_fout != None): write_loss(validation_losses, loss_label, val_fout) # calculate and apply gradient grad = tape.gradient(applicable_loss, model.trainable_variables) # THIS SHIT DOESNT WORK AND IDK WHY default_opt.apply_gradients(zip(grad, model.trainable_variables)) overall_train_loss = np.mean(applicable_loss) overall_val_loss = np.mean(visible_loss) # CLI debug messages # print(colored('>>> Overall Training Loss: ', 'green') + colored(str(overall_train_loss), 'green', attrs=['bold', 'reverse'])) # print(colored('>>> Overall Validation Loss: ', 'green') + colored(str(overall_val_loss), 'green', attrs=['bold', 'reverse'])) return overall_train_loss, overall_val_loss
input_path) # parse input if (unpaired_input.size == 0): print(colored('skipped {file}'.format(**locals()), 'red')) continue # create mel spectrogram unpaired_input_ml = loader.get_mel_spec(unpaired_input, mel_res, sr, window_size, hop_len) # get label for input unpaired_label, bpm = loader.parse_label(file, label_data_path) unpaired_label = sync.trim_front( unpaired_label) # trimming the MIDI and syncying the data input, label = sync.sync_data(unpaired_input_ml, unpaired_label, bpm, hop_len) # pair IO # 7480_4 cocks it up label = np.array(loader.encode_multihot(label)) # encode label input = np.reshape( input, (input.shape[0], input.shape[1], input.shape[2], 1)) # reshape to a tensor which the neural net can use X.append(input) # add to stash temp_out.append(label) # add to stash y = np.concatenate(temp_out) # TODO: implement make shift early stopping system # actual training part # STEP 1: Update status bar header = colored(
label = sync.trim_front(label) sync_in, sync_la = sync.sync_data(ML, label, bpm, 2048) sync_in.shape 112 / 14 sync_in2, sync_la2 = sync.sync_data(ML2, label2, bpm2, 512) np.concatenate(sync_in).shape plt.plot([sum(i) for i in np.concatenate(sync_in)]) plt.plot(np.concatenate([[sum(i)] * 8 for i in sync_la]), color='green') # this is the midi sound sync_in2.shape np.array(loader.encode_multihot(sync_la2)).shape for i in sync_in: print(i.shape) np.array(loader.encode_multihot(sync_la)).shape np.array(loader.encode_multihot(sync_la2)).shape sync_in.shape sync_in2.shape # >>> (16, 7, 128) <- there are 16 notes, with 7 columns in each, and 128 bins per column len(sync_la) # >>> 16 plt.imshow(sync_in[0])