TensorFlow Addons Networks: NMT sekwencja do sekwencji z mechanizmem uwagi

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Przegląd

Notebook ten daje krótkie wprowadzenie do sekwencji do sekwencji modelu architektury w tym noteboook ty szeroko obejmują cztery istotne zagadnienia niezbędne dla Neural tłumaczenia maszynowego:

  • Czyszczenie danych
  • Przygotowywanie danych
  • Model translacji neuronowej z uwagą
  • Ostateczna Translation z tf.addons.seq2seq.BasicDecoder i tf.addons.seq2seq.BeamSearchDecoder

Podstawową ideą takiego modelu jest jednak tylko architektura kodera-dekodera. Sieci te są zwykle używane do różnych zadań, takich jak podsumowanie tekstu, tłumaczenie maszynowe, tworzenie podpisów graficznych itp. Ten samouczek zapewnia praktyczne zrozumienie pojęcia, wyjaśniając żargon techniczny w razie potrzeby. Skupiasz się na zadaniu Neural Machine Translation (NMT), które było pierwszym testem dla modeli seq2seq.

Ustawiać

pip install tensorflow-addons==0.11.2
import tensorflow as tf
import tensorflow_addons as tfa

import matplotlib.pyplot as plt
import matplotlib.ticker as ticker
from sklearn.model_selection import train_test_split

import unicodedata
import re
import numpy as np
import os
import io
import time

Czyszczenie i przygotowywanie danych

Będziesz korzystać z zestawu danych dostarczonych przez język http://www.manythings.org/anki/ Ten zestaw danych zawiera pary tłumaczy w formacie:


  May I borrow this book?    ¿Puedo tomar prestado este libro?

Dostępnych jest wiele języków, ale będziesz używać zestawu danych angielsko-hiszpański. Po pobraniu zbioru danych wykonaj poniższe czynności, aby przygotować dane:

  1. Dodaj znacznik początku i końca do każdego zdania.
  2. Wyczyść zdania, usuwając znaki specjalne.
  3. Utwórz słownik z indeksem słów (mapowanie z word → id) i indeksem odwrotnym (mapowanie z id → word).
  4. Uzupełnij każde zdanie do maksymalnej długości. (Dlaczego? Musisz ustalić maksymalną długość wejść do enkoderów rekurencyjnych)
def download_nmt():
    path_to_zip = tf.keras.utils.get_file(
    'spa-eng.zip', origin='http://storage.googleapis.com/download.tensorflow.org/data/spa-eng.zip',
    extract=True)

    path_to_file = os.path.dirname(path_to_zip)+"/spa-eng/spa.txt"
    return path_to_file

Zdefiniuj klasę NMTDataset z niezbędnymi funkcjami, aby wykonać kroki od 1 do 4.

call() zwróci:

  1. train_dataset i val_dataset : tf.data.Dataset obiektów
  2. inp_lang_tokenizer i targ_lang_tokenizer : tf.keras.preprocessing.text.Tokenizer obiektów
class NMTDataset:
    def __init__(self, problem_type='en-spa'):
        self.problem_type = 'en-spa'
        self.inp_lang_tokenizer = None
        self.targ_lang_tokenizer = None


    def unicode_to_ascii(self, s):
        return ''.join(c for c in unicodedata.normalize('NFD', s) if unicodedata.category(c) != 'Mn')

    ## Step 1 and Step 2 
    def preprocess_sentence(self, w):
        w = self.unicode_to_ascii(w.lower().strip())

        # creating a space between a word and the punctuation following it
        # eg: "he is a boy." => "he is a boy ."
        # Reference:- https://stackoverflow.com/questions/3645931/python-padding-punctuation-with-white-spaces-keeping-punctuation
        w = re.sub(r"([?.!,¿])", r" \1 ", w)
        w = re.sub(r'[" "]+', " ", w)

        # replacing everything with space except (a-z, A-Z, ".", "?", "!", ",")
        w = re.sub(r"[^a-zA-Z?.!,¿]+", " ", w)

        w = w.strip()

        # adding a start and an end token to the sentence
        # so that the model know when to start and stop predicting.
        w = '<start> ' + w + ' <end>'
        return w

    def create_dataset(self, path, num_examples):
        # path : path to spa-eng.txt file
        # num_examples : Limit the total number of training example for faster training (set num_examples = len(lines) to use full data)
        lines = io.open(path, encoding='UTF-8').read().strip().split('\n')
        word_pairs = [[self.preprocess_sentence(w) for w in l.split('\t')]  for l in lines[:num_examples]]

        return zip(*word_pairs)

    # Step 3 and Step 4
    def tokenize(self, lang):
        # lang = list of sentences in a language

        # print(len(lang), "example sentence: {}".format(lang[0]))
        lang_tokenizer = tf.keras.preprocessing.text.Tokenizer(filters='', oov_token='<OOV>')
        lang_tokenizer.fit_on_texts(lang)

        ## tf.keras.preprocessing.text.Tokenizer.texts_to_sequences converts string (w1, w2, w3, ......, wn) 
        ## to a list of correspoding integer ids of words (id_w1, id_w2, id_w3, ...., id_wn)
        tensor = lang_tokenizer.texts_to_sequences(lang) 

        ## tf.keras.preprocessing.sequence.pad_sequences takes argument a list of integer id sequences 
        ## and pads the sequences to match the longest sequences in the given input
        tensor = tf.keras.preprocessing.sequence.pad_sequences(tensor, padding='post')

        return tensor, lang_tokenizer

    def load_dataset(self, path, num_examples=None):
        # creating cleaned input, output pairs
        targ_lang, inp_lang = self.create_dataset(path, num_examples)

        input_tensor, inp_lang_tokenizer = self.tokenize(inp_lang)
        target_tensor, targ_lang_tokenizer = self.tokenize(targ_lang)

        return input_tensor, target_tensor, inp_lang_tokenizer, targ_lang_tokenizer

    def call(self, num_examples, BUFFER_SIZE, BATCH_SIZE):
        file_path = download_nmt()
        input_tensor, target_tensor, self.inp_lang_tokenizer, self.targ_lang_tokenizer = self.load_dataset(file_path, num_examples)

        input_tensor_train, input_tensor_val, target_tensor_train, target_tensor_val = train_test_split(input_tensor, target_tensor, test_size=0.2)

        train_dataset = tf.data.Dataset.from_tensor_slices((input_tensor_train, target_tensor_train))
        train_dataset = train_dataset.shuffle(BUFFER_SIZE).batch(BATCH_SIZE, drop_remainder=True)

        val_dataset = tf.data.Dataset.from_tensor_slices((input_tensor_val, target_tensor_val))
        val_dataset = val_dataset.batch(BATCH_SIZE, drop_remainder=True)

        return train_dataset, val_dataset, self.inp_lang_tokenizer, self.targ_lang_tokenizer
BUFFER_SIZE = 32000
BATCH_SIZE = 64
# Let's limit the #training examples for faster training
num_examples = 30000

dataset_creator = NMTDataset('en-spa')
train_dataset, val_dataset, inp_lang, targ_lang = dataset_creator.call(num_examples, BUFFER_SIZE, BATCH_SIZE)
example_input_batch, example_target_batch = next(iter(train_dataset))
example_input_batch.shape, example_target_batch.shape
(TensorShape([64, 16]), TensorShape([64, 11]))

Niektóre ważne parametry

vocab_inp_size = len(inp_lang.word_index)+1
vocab_tar_size = len(targ_lang.word_index)+1
max_length_input = example_input_batch.shape[1]
max_length_output = example_target_batch.shape[1]

embedding_dim = 256
units = 1024
steps_per_epoch = num_examples//BATCH_SIZE
print("max_length_english, max_length_spanish, vocab_size_english, vocab_size_spanish")
max_length_input, max_length_output, vocab_inp_size, vocab_tar_size
max_length_spanish, max_length_english, vocab_size_spanish, vocab_size_english
(16, 11, 9415, 4936)
##### 

class Encoder(tf.keras.Model):
  def __init__(self, vocab_size, embedding_dim, enc_units, batch_sz):
    super(Encoder, self).__init__()
    self.batch_sz = batch_sz
    self.enc_units = enc_units
    self.embedding = tf.keras.layers.Embedding(vocab_size, embedding_dim)

    ##-------- LSTM layer in Encoder ------- ##
    self.lstm_layer = tf.keras.layers.LSTM(self.enc_units,
                                   return_sequences=True,
                                   return_state=True,
                                   recurrent_initializer='glorot_uniform')



  def call(self, x, hidden):
    x = self.embedding(x)
    output, h, c = self.lstm_layer(x, initial_state = hidden)
    return output, h, c

  def initialize_hidden_state(self):
    return [tf.zeros((self.batch_sz, self.enc_units)), tf.zeros((self.batch_sz, self.enc_units))]
## Test Encoder Stack

encoder = Encoder(vocab_inp_size, embedding_dim, units, BATCH_SIZE)


# sample input
sample_hidden = encoder.initialize_hidden_state()
sample_output, sample_h, sample_c = encoder(example_input_batch, sample_hidden)
print ('Encoder output shape: (batch size, sequence length, units) {}'.format(sample_output.shape))
print ('Encoder h vecotr shape: (batch size, units) {}'.format(sample_h.shape))
print ('Encoder c vector shape: (batch size, units) {}'.format(sample_c.shape))
Encoder output shape: (batch size, sequence length, units) (64, 16, 1024)
Encoder h vecotr shape: (batch size, units) (64, 1024)
Encoder c vector shape: (batch size, units) (64, 1024)
class Decoder(tf.keras.Model):
  def __init__(self, vocab_size, embedding_dim, dec_units, batch_sz, attention_type='luong'):
    super(Decoder, self).__init__()
    self.batch_sz = batch_sz
    self.dec_units = dec_units
    self.attention_type = attention_type

    # Embedding Layer
    self.embedding = tf.keras.layers.Embedding(vocab_size, embedding_dim)

    #Final Dense layer on which softmax will be applied
    self.fc = tf.keras.layers.Dense(vocab_size)

    # Define the fundamental cell for decoder recurrent structure
    self.decoder_rnn_cell = tf.keras.layers.LSTMCell(self.dec_units)



    # Sampler
    self.sampler = tfa.seq2seq.sampler.TrainingSampler()

    # Create attention mechanism with memory = None
    self.attention_mechanism = self.build_attention_mechanism(self.dec_units, 
                                                              None, self.batch_sz*[max_length_input], self.attention_type)

    # Wrap attention mechanism with the fundamental rnn cell of decoder
    self.rnn_cell = self.build_rnn_cell(batch_sz)

    # Define the decoder with respect to fundamental rnn cell
    self.decoder = tfa.seq2seq.BasicDecoder(self.rnn_cell, sampler=self.sampler, output_layer=self.fc)


  def build_rnn_cell(self, batch_sz):
    rnn_cell = tfa.seq2seq.AttentionWrapper(self.decoder_rnn_cell, 
                                  self.attention_mechanism, attention_layer_size=self.dec_units)
    return rnn_cell

  def build_attention_mechanism(self, dec_units, memory, memory_sequence_length, attention_type='luong'):
    # ------------- #
    # typ: Which sort of attention (Bahdanau, Luong)
    # dec_units: final dimension of attention outputs 
    # memory: encoder hidden states of shape (batch_size, max_length_input, enc_units)
    # memory_sequence_length: 1d array of shape (batch_size) with every element set to max_length_input (for masking purpose)

    if(attention_type=='bahdanau'):
      return tfa.seq2seq.BahdanauAttention(units=dec_units, memory=memory, memory_sequence_length=memory_sequence_length)
    else:
      return tfa.seq2seq.LuongAttention(units=dec_units, memory=memory, memory_sequence_length=memory_sequence_length)

  def build_initial_state(self, batch_sz, encoder_state, Dtype):
    decoder_initial_state = self.rnn_cell.get_initial_state(batch_size=batch_sz, dtype=Dtype)
    decoder_initial_state = decoder_initial_state.clone(cell_state=encoder_state)
    return decoder_initial_state


  def call(self, inputs, initial_state):
    x = self.embedding(inputs)
    outputs, _, _ = self.decoder(x, initial_state=initial_state, sequence_length=self.batch_sz*[max_length_output-1])
    return outputs
# Test decoder stack

decoder = Decoder(vocab_tar_size, embedding_dim, units, BATCH_SIZE, 'luong')
sample_x = tf.random.uniform((BATCH_SIZE, max_length_output))
decoder.attention_mechanism.setup_memory(sample_output)
initial_state = decoder.build_initial_state(BATCH_SIZE, [sample_h, sample_c], tf.float32)


sample_decoder_outputs = decoder(sample_x, initial_state)

print("Decoder Outputs Shape: ", sample_decoder_outputs.rnn_output.shape)
Decoder Outputs Shape:  (64, 10, 4936)

Zdefiniuj optymalizator i funkcję straty

optimizer = tf.keras.optimizers.Adam()


def loss_function(real, pred):
  # real shape = (BATCH_SIZE, max_length_output)
  # pred shape = (BATCH_SIZE, max_length_output, tar_vocab_size )
  cross_entropy = tf.keras.losses.SparseCategoricalCrossentropy(from_logits=True, reduction='none')
  loss = cross_entropy(y_true=real, y_pred=pred)
  mask = tf.logical_not(tf.math.equal(real,0))   #output 0 for y=0 else output 1
  mask = tf.cast(mask, dtype=loss.dtype)  
  loss = mask* loss
  loss = tf.reduce_mean(loss)
  return loss

Punkty kontrolne (zapisywanie oparte na obiektach)

checkpoint_dir = './training_checkpoints'
checkpoint_prefix = os.path.join(checkpoint_dir, "ckpt")
checkpoint = tf.train.Checkpoint(optimizer=optimizer,
                                 encoder=encoder,
                                 decoder=decoder)

Operacje z jednym etapem pociągu

@tf.function
def train_step(inp, targ, enc_hidden):
  loss = 0

  with tf.GradientTape() as tape:
    enc_output, enc_h, enc_c = encoder(inp, enc_hidden)


    dec_input = targ[ : , :-1 ] # Ignore <end> token
    real = targ[ : , 1: ]         # ignore <start> token

    # Set the AttentionMechanism object with encoder_outputs
    decoder.attention_mechanism.setup_memory(enc_output)

    # Create AttentionWrapperState as initial_state for decoder
    decoder_initial_state = decoder.build_initial_state(BATCH_SIZE, [enc_h, enc_c], tf.float32)
    pred = decoder(dec_input, decoder_initial_state)
    logits = pred.rnn_output
    loss = loss_function(real, logits)

  variables = encoder.trainable_variables + decoder.trainable_variables
  gradients = tape.gradient(loss, variables)
  optimizer.apply_gradients(zip(gradients, variables))

  return loss

Trenuj modelkę

EPOCHS = 10

for epoch in range(EPOCHS):
  start = time.time()

  enc_hidden = encoder.initialize_hidden_state()
  total_loss = 0
  # print(enc_hidden[0].shape, enc_hidden[1].shape)

  for (batch, (inp, targ)) in enumerate(train_dataset.take(steps_per_epoch)):
    batch_loss = train_step(inp, targ, enc_hidden)
    total_loss += batch_loss

    if batch % 100 == 0:
      print('Epoch {} Batch {} Loss {:.4f}'.format(epoch + 1,
                                                   batch,
                                                   batch_loss.numpy()))
  # saving (checkpoint) the model every 2 epochs
  if (epoch + 1) % 2 == 0:
    checkpoint.save(file_prefix = checkpoint_prefix)

  print('Epoch {} Loss {:.4f}'.format(epoch + 1,
                                      total_loss / steps_per_epoch))
  print('Time taken for 1 epoch {} sec\n'.format(time.time() - start))
Epoch 1 Batch 0 Loss 5.1692
Epoch 1 Batch 100 Loss 2.2288
Epoch 1 Batch 200 Loss 1.9930
Epoch 1 Batch 300 Loss 1.7783
Epoch 1 Loss 1.6975
Time taken for 1 epoch 37.26002788543701 sec

Epoch 2 Batch 0 Loss 1.6408
Epoch 2 Batch 100 Loss 1.5767
Epoch 2 Batch 200 Loss 1.4054
Epoch 2 Batch 300 Loss 1.3755
Epoch 2 Loss 1.1412
Time taken for 1 epoch 30.0094051361084 sec

Epoch 3 Batch 0 Loss 1.0296
Epoch 3 Batch 100 Loss 1.0306
Epoch 3 Batch 200 Loss 1.0675
Epoch 3 Batch 300 Loss 0.9574
Epoch 3 Loss 0.8037
Time taken for 1 epoch 28.983767986297607 sec

Epoch 4 Batch 0 Loss 0.5923
Epoch 4 Batch 100 Loss 0.7533
Epoch 4 Batch 200 Loss 0.7397
Epoch 4 Batch 300 Loss 0.6779
Epoch 4 Loss 0.5419
Time taken for 1 epoch 29.649972200393677 sec

Epoch 5 Batch 0 Loss 0.4320
Epoch 5 Batch 100 Loss 0.4349
Epoch 5 Batch 200 Loss 0.4686
Epoch 5 Batch 300 Loss 0.4748
Epoch 5 Loss 0.3827
Time taken for 1 epoch 29.06334638595581 sec

Epoch 6 Batch 0 Loss 0.3422
Epoch 6 Batch 100 Loss 0.3052
Epoch 6 Batch 200 Loss 0.3288
Epoch 6 Batch 300 Loss 0.3216
Epoch 6 Loss 0.2814
Time taken for 1 epoch 29.57170796394348 sec

Epoch 7 Batch 0 Loss 0.2129
Epoch 7 Batch 100 Loss 0.2382
Epoch 7 Batch 200 Loss 0.2406
Epoch 7 Batch 300 Loss 0.2792
Epoch 7 Loss 0.2162
Time taken for 1 epoch 28.95500087738037 sec

Epoch 8 Batch 0 Loss 0.2073
Epoch 8 Batch 100 Loss 0.2095
Epoch 8 Batch 200 Loss 0.1962
Epoch 8 Batch 300 Loss 0.1879
Epoch 8 Loss 0.1794
Time taken for 1 epoch 29.70877432823181 sec

Epoch 9 Batch 0 Loss 0.1517
Epoch 9 Batch 100 Loss 0.2231
Epoch 9 Batch 200 Loss 0.2203
Epoch 9 Batch 300 Loss 0.2282
Epoch 9 Loss 0.1496
Time taken for 1 epoch 29.20821261405945 sec

Epoch 10 Batch 0 Loss 0.1204
Epoch 10 Batch 100 Loss 0.1370
Epoch 10 Batch 200 Loss 0.1778
Epoch 10 Batch 300 Loss 0.2069
Epoch 10 Loss 0.1316
Time taken for 1 epoch 29.576894283294678 sec

Użyj tf-addons BasicDecoder do dekodowania

def evaluate_sentence(sentence):
  sentence = dataset_creator.preprocess_sentence(sentence)

  inputs = [inp_lang.word_index[i] for i in sentence.split(' ')]
  inputs = tf.keras.preprocessing.sequence.pad_sequences([inputs],
                                                          maxlen=max_length_input,
                                                          padding='post')
  inputs = tf.convert_to_tensor(inputs)
  inference_batch_size = inputs.shape[0]
  result = ''

  enc_start_state = [tf.zeros((inference_batch_size, units)), tf.zeros((inference_batch_size,units))]
  enc_out, enc_h, enc_c = encoder(inputs, enc_start_state)

  dec_h = enc_h
  dec_c = enc_c

  start_tokens = tf.fill([inference_batch_size], targ_lang.word_index['<start>'])
  end_token = targ_lang.word_index['<end>']

  greedy_sampler = tfa.seq2seq.GreedyEmbeddingSampler()

  # Instantiate BasicDecoder object
  decoder_instance = tfa.seq2seq.BasicDecoder(cell=decoder.rnn_cell, sampler=greedy_sampler, output_layer=decoder.fc)
  # Setup Memory in decoder stack
  decoder.attention_mechanism.setup_memory(enc_out)

  # set decoder_initial_state
  decoder_initial_state = decoder.build_initial_state(inference_batch_size, [enc_h, enc_c], tf.float32)


  ### Since the BasicDecoder wraps around Decoder's rnn cell only, you have to ensure that the inputs to BasicDecoder 
  ### decoding step is output of embedding layer. tfa.seq2seq.GreedyEmbeddingSampler() takes care of this. 
  ### You only need to get the weights of embedding layer, which can be done by decoder.embedding.variables[0] and pass this callabble to BasicDecoder's call() function

  decoder_embedding_matrix = decoder.embedding.variables[0]

  outputs, _, _ = decoder_instance(decoder_embedding_matrix, start_tokens = start_tokens, end_token= end_token, initial_state=decoder_initial_state)
  return outputs.sample_id.numpy()

def translate(sentence):
  result = evaluate_sentence(sentence)
  print(result)
  result = targ_lang.sequences_to_texts(result)
  print('Input: %s' % (sentence))
  print('Predicted translation: {}'.format(result))

Przywróć najnowszy punkt kontrolny i przetestuj

# restoring the latest checkpoint in checkpoint_dir
checkpoint.restore(tf.train.latest_checkpoint(checkpoint_dir))
<tensorflow.python.training.tracking.util.CheckpointLoadStatus at 0x7f9499417390>
translate(u'hace mucho frio aqui.')
[[ 11  12  49 224  40   4   3]]
Input: hace mucho frio aqui.
Predicted translation: ['it s very pretty here . <end>']
translate(u'esta es mi vida.')
[[ 20   9  22 190   4   3]]
Input: esta es mi vida.
Predicted translation: ['this is my life . <end>']
translate(u'¿todavia estan en casa?')
[[25  7 90  8  3]]
Input: ¿todavia estan en casa?
Predicted translation: ['are you home ? <end>']
# wrong translation
translate(u'trata de averiguarlo.')
[[126  16 892  11  75   4   3]]
Input: trata de averiguarlo.
Predicted translation: ['try to figure it out . <end>']

Użyj tf-addons BeamSearchDecoder

def beam_evaluate_sentence(sentence, beam_width=3):
  sentence = dataset_creator.preprocess_sentence(sentence)

  inputs = [inp_lang.word_index[i] for i in sentence.split(' ')]
  inputs = tf.keras.preprocessing.sequence.pad_sequences([inputs],
                                                          maxlen=max_length_input,
                                                          padding='post')
  inputs = tf.convert_to_tensor(inputs)
  inference_batch_size = inputs.shape[0]
  result = ''

  enc_start_state = [tf.zeros((inference_batch_size, units)), tf.zeros((inference_batch_size,units))]
  enc_out, enc_h, enc_c = encoder(inputs, enc_start_state)

  dec_h = enc_h
  dec_c = enc_c

  start_tokens = tf.fill([inference_batch_size], targ_lang.word_index['<start>'])
  end_token = targ_lang.word_index['<end>']

  # From official documentation
  # NOTE If you are using the BeamSearchDecoder with a cell wrapped in AttentionWrapper, then you must ensure that:
  # The encoder output has been tiled to beam_width via tfa.seq2seq.tile_batch (NOT tf.tile).
  # The batch_size argument passed to the get_initial_state method of this wrapper is equal to true_batch_size * beam_width.
  # The initial state created with get_initial_state above contains a cell_state value containing properly tiled final state from the encoder.

  enc_out = tfa.seq2seq.tile_batch(enc_out, multiplier=beam_width)
  decoder.attention_mechanism.setup_memory(enc_out)
  print("beam_with * [batch_size, max_length_input, rnn_units] :  3 * [1, 16, 1024]] :", enc_out.shape)

  # set decoder_inital_state which is an AttentionWrapperState considering beam_width
  hidden_state = tfa.seq2seq.tile_batch([enc_h, enc_c], multiplier=beam_width)
  decoder_initial_state = decoder.rnn_cell.get_initial_state(batch_size=beam_width*inference_batch_size, dtype=tf.float32)
  decoder_initial_state = decoder_initial_state.clone(cell_state=hidden_state)

  # Instantiate BeamSearchDecoder
  decoder_instance = tfa.seq2seq.BeamSearchDecoder(decoder.rnn_cell,beam_width=beam_width, output_layer=decoder.fc)
  decoder_embedding_matrix = decoder.embedding.variables[0]

  # The BeamSearchDecoder object's call() function takes care of everything.
  outputs, final_state, sequence_lengths = decoder_instance(decoder_embedding_matrix, start_tokens=start_tokens, end_token=end_token, initial_state=decoder_initial_state)
  # outputs is tfa.seq2seq.FinalBeamSearchDecoderOutput object. 
  # The final beam predictions are stored in outputs.predicted_id
  # outputs.beam_search_decoder_output is a tfa.seq2seq.BeamSearchDecoderOutput object which keep tracks of beam_scores and parent_ids while performing a beam decoding step
  # final_state = tfa.seq2seq.BeamSearchDecoderState object.
  # Sequence Length = [inference_batch_size, beam_width] details the maximum length of the beams that are generated


  # outputs.predicted_id.shape = (inference_batch_size, time_step_outputs, beam_width)
  # outputs.beam_search_decoder_output.scores.shape = (inference_batch_size, time_step_outputs, beam_width)
  # Convert the shape of outputs and beam_scores to (inference_batch_size, beam_width, time_step_outputs)
  final_outputs = tf.transpose(outputs.predicted_ids, perm=(0,2,1))
  beam_scores = tf.transpose(outputs.beam_search_decoder_output.scores, perm=(0,2,1))

  return final_outputs.numpy(), beam_scores.numpy()
def beam_translate(sentence):
  result, beam_scores = beam_evaluate_sentence(sentence)
  print(result.shape, beam_scores.shape)
  for beam, score in zip(result, beam_scores):
    print(beam.shape, score.shape)
    output = targ_lang.sequences_to_texts(beam)
    output = [a[:a.index('<end>')] for a in output]
    beam_score = [a.sum() for a in score]
    print('Input: %s' % (sentence))
    for i in range(len(output)):
      print('{} Predicted translation: {}  {}'.format(i+1, output[i], beam_score[i]))
beam_translate(u'hace mucho frio aqui.')
beam_with * [batch_size, max_length_input, rnn_units] :  3 * [1, 16, 1024]] : (3, 16, 1024)
(1, 3, 7) (1, 3, 7)
(3, 7) (3, 7)
Input: hace mucho frio aqui.
1 Predicted translation: it s very pretty here .   -4.117094039916992
2 Predicted translation: it s very cold here .   -14.85302734375
3 Predicted translation: it s very pretty news .   -25.59416389465332
beam_translate(u'¿todavia estan en casa?')
beam_with * [batch_size, max_length_input, rnn_units] :  3 * [1, 16, 1024]] : (3, 16, 1024)
(1, 3, 7) (1, 3, 7)
(3, 7) (3, 7)
Input: ¿todavia estan en casa?
1 Predicted translation: are you still home ?   -4.036754131317139
2 Predicted translation: are you still at home ?   -15.306867599487305
3 Predicted translation: are you still go home ?   -20.533388137817383