4

I am trying to create model that is trained on large music dataset. The midi files are converted into numpy arrays. Since LSTM requires sequential data, the dataset size becomes so huge on converting into a sequence for the LSTM.

I convert the midi notes into index based on the keynote and duration, so I get 6 classes for C4 key. Likewise I get C3 to B5 so totally 288 classes along with classes for rest periods.

The converted format of a single midi looks like this.

midi = [0,23,54,180,23,45,34,.....];

For training the LSTM, the x and y becomes

x = [[0,23,54..45],[23,54,..,34],...];

y=[[34],[76],...]

The values in x and y are further transformed into one-hot encodings. Hence the size of the data becomes huge for just 60 small mid files, but I have 1700 files. How can I train the model with this amount of files. I checked ImageGenerator but it requires data to be in separate class directories. How to achieve this?

6
  • Is there any specific reason for using one-hot encoding?
    – Darshit
    Mar 2, 2020 at 10:31
  • No specific reason, is it possible to train just with x = [[0,23,54..45],[23,54,..,34],...]; y=[[34],[76],...]. Instead of converting it into one-hot encoding?
    – R Nanthak
    Mar 2, 2020 at 10:45
  • one-hot encoding is to convert text data in to numerical forms, so ML model can use it. If you dataset is already in numerical form there's no need to use one-hot encoding. Another thing one-hot encoding uses huge amount of memory if there are lots of unique words in dataset, if possible use TF-IDF or Word2Vec transformation.
    – Darshit
    Mar 2, 2020 at 11:02
  • If I use one-hot encoding the training takes increased amount of time and validation loss is high. Why is this?
    – R Nanthak
    Mar 2, 2020 at 13:16
  • Training time increases as amount of data increases(representation size grows in one-hot encoding compare to other transformation). LSTM model is sequential one, it's prediction depends on the previous sequence of the data, so I suspect with one-hot encoding you might get sequence of long ZEROs which is creating this problem.
    – Darshit
    Mar 3, 2020 at 10:23

2 Answers 2

6

You should generate you training data on the fly, during the training itself. Based on tf documentation, you can write your own generator to use as training data, or inheritate from Sequence.

The first option should look like

def create_data_generator(your_files):
    raw_midi_data = process_files(your_files)
    seq_size = 32

    def _my_generator():
        i = 0 
        while True:
            x = raw_midi_data[i:i + seq_size]
            y = raw_midi_data[i + seq_size]
            i = (i + 1) % (len(raw_midi_data) - seq_size)
            yield x, y

    return _my_generator()

And then call it with (assuming tf >= 2.0)

generator = create_data_generator(your_files)
model.fit(x=generator, ...)

If you are using "old" Keras (from before tensorflow 2.0) which Keras team itself does not recommend, you should use fit_generator instead:

model.fit_generator(generator, ...)

With this solution, you only store your data in memory once, there is no duplication due to overlapping sequences.

7
  • Thanks for answering, I am implementing your answer, I will reply you soon.
    – R Nanthak
    Mar 2, 2020 at 13:11
  • is that model.fit_generator?@Théo Rubenach
    – R Nanthak
    Mar 2, 2020 at 17:54
  • Your solution doesn't work, it wants y in parameter.
    – R Nanthak
    Mar 3, 2020 at 5:46
  • Then I assume you're using "old" Keras (doc at keras.io). I updated my answer for both version of Keras. Mar 3, 2020 at 9:55
  • Thanks, I used sequence generator and it worked well.
    – R Nanthak
    Mar 3, 2020 at 12:24
1

I used a generator class for this problem used the following code. The generator is modified for my purpose. Memory usage is dramatically reduced.

class Generator(Sequence):

    def __init__(self, x_set, y_set, batch_size=4):
        self.x, self.y = x_set, y_set

        self.batch_size = batch_size
        self.indices = np.arange(len(self.x))

    def __len__(self):
        return int(np.ceil(len(self.x) / self.batch_size))

    def __getitem__(self, idx):
        inds = self.indices[idx * self.batch_size:(idx + 1) * self.batch_size]
        batch_x = []
        batch_y = []
        for ind in inds:
            ip = []

            for q in self.x[ind]:
                o = np.zeros(323)
                o[int(q)] = 1
                ip.append(o)
            batch_x.append(ip)
            hot_encoded = []
            for val in self.y[ind]:

                t = np.zeros(323)
                t[int(val)] = 1
                hot_encoded.append(t)
            batch_y.append(hot_encoded)

        return np.array(batch_x), np.array(batch_y)

    def on_epoch_end(self):
        # np.random.shuffle(self.indices)
        np.random.shuffle(self.indices)

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.