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Here, I have LSTM Autoencoder written in Keras. I want to convert the code to Chainer.

import numpy as np
from keras.layers import Input, GRU
from keras.models import Model

input_feat = Input(shape=(30, 2000))
l = GRU( 100, return_sequences=True, activation="tanh", recurrent_activation="hard_sigmoid")(input_feat)
l = GRU(2000, return_sequences=True, activation="tanh", recurrent_activation="hard_sigmoid")(l)
model = Model(input_feat, l)
model.compile(optimizer="RMSprop", loss="mean_squared_error")

feat = np.load("feat.npy")
model.fit(feat, feat[:, ::-1, :], epochs=200, batch_size=250)

feat is numpy whose dimension is (269, 30, 2000). I could run above code and the result was reasonable. I had written below Chainer code.

import numpy as np
from chainer import Chain, Variable, optimizers
import chainer.functions as F
import chainer.links as L

class GRUAutoEncoder(Chain):
    def __init__(self):
        super().__init__()
        with self.init_scope():
            self.encode = L.GRU(2000, 100)
            self.decode = L.GRU(100, 2000)

    def __call__(self, h, mode):
        if mode == "encode":
            h = F.tanh(self.encode(h))
            return h 

        if mode == "decode":
            h = F.tanh(self.decode(h))
            return h

    def reset(self):
        self.encode.reset_state()
        self.decode.reset_state()

def main():
    feat = np.load("feat.npy") #(269, 30, 2000)

    gru_autoencoder = GRUAutoEncoder()
    optimizer = optimizers.RMSprop(lr=0.01).setup(gru_autoencoder)

    N = len(feat)
    batch_size = 250
    for epoch in range(200):
        index = np.random.randint(0, N-batch_size+1)
        input_splices = feat[index:index+batch_size] #(250, 30, 2000)
        #Encoding
        input_vector = np.zeros((30, batch_size, 2000), dtype="float32")
        h = []
        for i in range(frame_rate):
            input_vector[i] = input_splices[:, i, :] #(250, 1, 2000)
            tmp = Variable(input_vector[i])
            h.append(gru_autoencoder(tmp, "encode")) #(250, 100)

        #Decoding
        output_vector = []
        for i in range(frame_rate):
            tmp = h[i]
            output_vector.append(gru_autoencoder(tmp, "decode"))

        x = input_vector[0]
        t = output_vector[0]
        for i in range(len(output_vector)):
            x = F.concat((x,input_vector[i]), axis=1)
            t = F.concat((t,output_vector[i]), axis=1)

        loss = F.mean_squared_error(x, t)
        gru_autoencoder.cleargrads()
        loss.backward()
        optimizer.update()
        gru_autoencoder.reset()

if __name__ == "__main__":
    main()

But the result of above code was not reasonable. I think the Chainer code has something wrong but I cannot find where it is.

In Keras code,

model.fit(feat, feat[:, ::-1, :])

So, I tried to reverse output_vector in Chainer code,

output_vector.reverse()

but the result was not still reasonable.

  • Should I use L.NStepGRU? – Sakurai.JJ Jan 21 at 6:30
0

.. note: This answer is a translation of [Japanese SO].(https://ja.stackoverflow.com/questions/52162/keras%E3%81%AE%E3%82%B3%E3%83%BC%E3%83%89%E3%82%92chainer%E3%81%AB%E6%9B%B8%E3%81%8D%E6%8F%9B%E3%81%88%E3%81%9F%E3%81%84lstm-autoencoder%E3%81%AE%E5%AE%9F%E8%A3%85/52213#52213)

  1. You should avoid using L.GRU and should use L.NStepGRU, because for L.GRU you have to write "recurrence-aware" code. In other words, you have to apply L.GRU multiple times to one timeseries, therefore "batch" must be treated with great care. L.NStepGRU (with n_layers=1) wraps the batch-processing, so it would be user-friendly.
  2. An instance of L.StepGRU takes two input arguments: one is initial state, and the other is a list of timeserieses, which composes a batch. Conventionally, the initial state is None.

Therefore, the whole answer for your question is as follows.

### dataset.py
from chainer.dataset import DatasetMixin

import numpy as np


class MyDataset(DatasetMixin):
    N_SAMPLES = 269
    N_TIMESERIES = 30
    N_DIMS = 2000

    def __init__(self):
        super().__init__()
        self.data = np.random.randn(self.N_SAMPLES, self.N_TIMESERIES, self.N_DIMS) \
            .astype(np.float32)

    def __len__(self):
        return self.N_SAMPLES

    def get_example(self, i):
        return self.data[i, :, :]


### model.py
import chainer
from chainer import links as L
from chainer import functions as F
from chainer.link import Chain


class MyModel(Chain):
    N_IN_CHANNEL = 2000
    N_HIDDEN_CHANNEL = 100
    N_OUT_CHANNEL = 2000

    def __init__(self):
        super().__init__()
        self.encoder = L.NStepGRU(n_layers=1, in_size=self.N_IN_CHANNEL, out_size=self.N_HIDDEN_CHANNEL, dropout=0)
        self.decoder = L.NStepGRU(n_layers=1, in_size=self.N_HIDDEN_CHANNEL, out_size=self.N_OUT_CHANNEL, dropout=0)

    def to_gpu(self, device=None):
        self.encoder.to_gpu(device)
        self.decoder.to_gpu(device)

    def to_cpu(self):
        self.encoder.to_cpu()
        self.decoder.to_cpu()

    @staticmethod
    def flip_list(source_list):
        return [F.flip(source, axis=1) for source in source_list]

    def __call__(self, source_list):
        """
        .. note:
            This implementation makes use of "auto-encoding"
            by avoiding redundant copy in GPU device.
            In the typical implementation, this function should receive
            both of ``source_list`` and ``target_list``.
        """
        target_list = self.flip_list(source_list)
        _, h_list = self.encoder(hx=None, xs=source_list)
        _, predicted_list = self.decoder(hx=None, xs=h_list)
        diff_list = [F.mean_squared_error(target, predicted).reshape((1,)) for target, predicted in zip(target_list, predicted_list)]
        loss = F.sum(F.concat(diff_list, axis=0))

        chainer.report({'loss': loss}, self)

        return loss


### converter.py (referring examples/seq2seq/seq2seq.py)
from chainer.dataset import to_device


def convert(batch, device):
    """
    .. note:
        batch must be list(batch_size) of array
    """
    if device is None:
        return batch
    else:
        return [to_device(device, x) for x in batch]


### train.py
from chainer.iterators import SerialIterator
from chainer.optimizers import RMSprop
from chainer.training.updaters import StandardUpdater
from chainer.training.trainer import Trainer

dataset = MyDataset()

BATCH_SIZE = 32
iterator = SerialIterator(dataset, BATCH_SIZE)

model = MyModel()
optimizer = RMSprop()
optimizer.setup(model)

updater = StandardUpdater(iterator, optimizer, convert, device=0)
trainer = Trainer(updater, (100, 'iteration'))

from chainer.training.extensions import snapshot_object
trainer.extend(snapshot_object(model, "model_iter_{.updater.iteration}"), trigger=(10, 'iteration'))

from chainer.training.extensions import LogReport, PrintReport, ProgressBar
trainer.extend(LogReport(['epoch', 'iteration', 'main/loss'], (1, 'iteration')))
trainer.extend(PrintReport(['epoch', 'iteration', 'main/loss']), trigger=(1, 'iteration'))
trainer.extend(ProgressBar(update_interval=1))

trainer.run()

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