#sequence_groups = np.real(data.transform.ifft(sequence_groups))
#
return sequence_groups
#### Load data
# sequence_groups[i] contains data for class i
# 4-dimensional data structure: (class, sequence_num, timestep, channel_num)
# Manually selecting different training and validation datasets
#training_sequence_groups, validation_sequence_groups = data.split(
# data.digits_session_7_dataset(channels=range(4, 8)), 1./6)
training_sequence_groups = transform_data(
data.combine([
data.digits_session_5_dataset(channels=range(4, 8)),
data.digits_session_6_dataset(channels=range(4, 8)),
# data.digits_session_7_dataset(channels=range(4, 8)),
# training_sequence_groups,
]))
validation_sequence_groups = transform_data(
data.combine([
# data.digits_session_5_dataset(channels=range(4, 8)),
# data.digits_session_6_dataset(channels=range(4, 8)),
data.digits_session_7_dataset(channels=range(4, 8)),
# validation_sequence_groups,
]))
#sequence_groups = transform_data(
# data.combine([
# data.digits_session_5_dataset(channels=range(4, 8)),
# data.digits_session_6_dataset(channels=range(4, 8)),
# data.digits_session_7_dataset(channels=range(4, 8)),
# ]))
#
#print map(len, sequence_groups)
#lens = map(len, data.get_inputs(sequence_groups)[0])
#print min(lens), np.mean(lens), max(lens)
# Split sequence_groups into training and validation data
#training_sequence_groups, validation_sequence_groups = data.split(sequence_groups, 1./6)
# Manually selecting different training and validation datasets
training_sequence_groups, validation_sequence_groups = data.split(
data.digits_session_dependence_3_dataset(channels=range(1, 8)), 1. / 6)
training_sequence_groups = transform_data(
data.combine([
# map(lambda x: x[:30], data.digits_session_dependence_1_dataset(channels=range(1, 8))),
# map(lambda x: x[:30], data.digits_session_dependence_2_dataset(channels=range(1, 8))),
# map(lambda x: x[:40], data.digits_session_dependence_3_dataset(channels=range(1, 8))),
training_sequence_groups,
]))
validation_sequence_groups = transform_data(
data.combine([
# map(lambda x: x[:30], data.digits_session_dependence_1_dataset(channels=range(1, 8))),
# map(lambda x: x[:30], data.digits_session_dependence_2_dataset(channels=range(1, 8))),
# map(lambda x: x[:40], data.digits_session_dependence_3_dataset(channels=range(1, 8))),
validation_sequence_groups,
]))
# Pads or truncates each sequence to length
length = 2000 # 300,600
training_sequence_groups = data.transform.pad_truncate(
training_sequence_groups, length)
validation_sequence_groups = data.transform.pad_truncate(
# setup logging
logging.basicConfig(level=logging.INFO)
batch_size = 32
device_name = "cuda" if torch.cuda.is_available() else "cpu"
# device_name = "cpu"
device = torch.device(device_name)
print("Device: %s" % device)
# Load data and make batches
train_dataset = LyricsDataset("data/preprocessed_lyrics.csv", limit=10000, device=device)
train_loader = torch.utils.data.DataLoader(
train_dataset,
batch_size=batch_size, shuffle=True, num_workers=0,
pin_memory=device_name == "cpu", collate_fn=lambda batch: combine(batch, device, "char_id_length"))
# CE Loss (NLL + Softmax)
criterion = nn.CrossEntropyLoss().to(device)
# Init model
model: LyricsGenerator = LyricsGenerator(device)
model = model.to(device)
model.train()
# Optimizer
optimizer = torch.optim.Adam(model.parameters(), lr=5e-4)
def prepare_target(target_ids, lengths, enforce_sorted=True):
lengths = lengths.squeeze(dim=1).squeeze(dim=1)
