update
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import torch
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import numpy as np
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import torch.nn as nn
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import keras
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import torch.optim as optim
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from nltk.translate.bleu_score import corpus_bleu
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import random
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import re
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import unicodedata
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from torchtext.data.metrics import bleu_score
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device = torch.device('cuda' if torch.cuda.is_available() else 'cpu')
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# Configuration
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batch_size = 64
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epochs = 350
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latent_dim = 256
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num_samples = 50000
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data_path = "fra.txt"
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# Data preparation
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# Preparing data
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def unicode_to_ascii(s):
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input_texts = []
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return ''.join(c for c in unicodedata.normalize('NFD', s)
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target_texts = []
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if unicodedata.category(c) != 'Mn')
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input_characters = set()
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target_characters = set()
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with open(data_path, "r", encoding="utf-8") as f:
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lines = f.read().split("\n")
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for line in lines[: min(num_samples, len(lines) - 1)]:
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input_text, target_text, _ = line.split("\t")
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target_text = "\t" + target_text + "\n"
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input_texts.append(input_text)
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target_texts.append(target_text)
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for char in input_text:
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if char not in input_characters:
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input_characters.add(char)
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for char in target_text:
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if char not in target_characters:
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target_characters.add(char)
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def preprocess_sentence(w):
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input_characters = sorted(list(input_characters))
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w = unicode_to_ascii(w.lower().strip())
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target_characters = sorted(list(target_characters))
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w = re.sub(r"([?.!,¿])", r" \1 ", w)
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num_encoder_tokens = len(input_characters)
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w = re.sub(r'[" "]+', " ", w)
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num_decoder_tokens = len(target_characters)
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w = re.sub(r"[^a-zA-Z?.!,¿]+", " ", w)
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max_encoder_seq_length = max([len(txt) for txt in input_texts])
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w = w.strip()
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max_decoder_seq_length = max([len(txt) for txt in target_texts])
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return w
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def read_langs(lang1, lang2, path):
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print("Number of samples:", len(input_texts))
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lines = open(path, encoding='utf-8').read().strip().split('\n')
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print("Number of unique input tokens:", num_encoder_tokens)
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pairs = []
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print("Number of unique output tokens:", num_decoder_tokens)
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for line in lines:
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print("Max sequence length for inputs:", max_encoder_seq_length)
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parts = line.split('\t')
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print("Max sequence length for outputs:", max_decoder_seq_length)
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if len(parts) >= 2:
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pairs.append([preprocess_sentence(parts[0]), preprocess_sentence(parts[1])])
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return pairs
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data_path = 'fra.txt'
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input_token_index = dict([(char, i) for i, char in enumerate(input_characters)])
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pairs = read_langs('eng', 'fra', data_path)
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target_token_index = dict([(char, i) for i, char in enumerate(target_characters)])
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# Vocabulary class
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encoder_input_data = np.zeros(
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class Vocabulary:
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(len(input_texts), max_encoder_seq_length, num_encoder_tokens),
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def __init__(self):
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dtype="float32",
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self.word2index = {}
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)
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self.index2word = {}
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decoder_input_data = np.zeros(
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self.word2count = {}
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(len(input_texts), max_decoder_seq_length, num_decoder_tokens),
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self.n_words = 0
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dtype="float32",
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self.add_word('<unk>')
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)
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self.add_word('<pad>')
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decoder_target_data = np.zeros(
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(len(input_texts), max_decoder_seq_length, num_decoder_tokens),
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dtype="float32",
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)
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def add_sentence(self, sentence):
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for i, (input_text, target_text) in enumerate(zip(input_texts, target_texts)):
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for word in sentence.split(' '):
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for t, char in enumerate(input_text):
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self.add_word(word)
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encoder_input_data[i, t, input_token_index[char]] = 1.0
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encoder_input_data[i, t + 1 :, input_token_index[" "]] = 1.0
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for t, char in enumerate(target_text):
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decoder_input_data[i, t, target_token_index[char]] = 1.0
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if t > 0:
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decoder_target_data[i, t - 1, target_token_index[char]] = 1.0
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decoder_input_data[i, t + 1 :, target_token_index[" "]] = 1.0
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decoder_target_data[i, t:, target_token_index[" "]] = 1.0
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def add_word(self, word):
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# Creating model
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if word not in self.word2index:
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encoder_inputs = keras.Input(shape=(None, num_encoder_tokens))
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self.word2index[word] = self.n_words
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encoder = keras.layers.LSTM(latent_dim, return_state=True)
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self.index2word[self.n_words] = word
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encoder_outputs, state_h, state_c = encoder(encoder_inputs)
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self.word2count[word] = 1
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encoder_states = [state_h, state_c]
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self.n_words += 1
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else:
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self.word2count[word] += 1
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def lookup(self, word):
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decoder_inputs = keras.Input(shape=(None, num_decoder_tokens))
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return self.word2index.get(word, self.word2index['<unk>'])
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decoder_lstm = keras.layers.LSTM(latent_dim, return_sequences=True, return_state=True)
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decoder_outputs, _, _ = decoder_lstm(decoder_inputs, initial_state=encoder_states)
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decoder_dense = keras.layers.Dense(num_decoder_tokens, activation="softmax")
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decoder_outputs = decoder_dense(decoder_outputs)
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eng_vocab = Vocabulary()
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model = keras.Model([encoder_inputs, decoder_inputs], decoder_outputs)
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fra_vocab = Vocabulary()
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for pair in pairs:
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# Creating the training model
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eng_vocab.add_sentence(pair[0])
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model.compile(
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fra_vocab.add_sentence(pair[1])
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optimizer="rmsprop", loss="categorical_crossentropy", metrics=["accuracy"]
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)
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model.fit(
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[encoder_input_data, decoder_input_data],
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decoder_target_data,
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batch_size=batch_size,
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epochs=epochs,
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validation_split=0.2,
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)
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model.save("s2s_model.keras")
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# Seq2Seq Model with Attention
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# Sampling
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class Encoder(nn.Module):
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model = keras.models.load_model("s2s_model.keras")
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def __init__(self, input_dim, emb_dim, hid_dim, n_layers, dropout):
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super().__init__()
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self.embedding = nn.Embedding(input_dim, emb_dim)
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self.rnn = nn.GRU(emb_dim, hid_dim, n_layers, dropout=dropout, bidirectional=True)
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self.fc = nn.Linear(hid_dim * 2, hid_dim)
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self.dropout = nn.Dropout(dropout)
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def forward(self, src):
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encoder_inputs = model.input[0]
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embedded = self.dropout(self.embedding(src))
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encoder_outputs, state_h_enc, state_c_enc = model.layers[2].output
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outputs, hidden = self.rnn(embedded)
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encoder_states = [state_h_enc, state_c_enc]
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# Sum bidirectional outputs
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encoder_model = keras.Model(encoder_inputs, encoder_states)
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hidden = torch.tanh(self.fc(torch.cat((hidden[-2,:,:], hidden[-1,:,:]), dim=1)))
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return outputs, hidden
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class Attention(nn.Module):
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decoder_inputs = model.input[1]
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def __init__(self, hid_dim):
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decoder_state_input_h = keras.Input(shape=(latent_dim,))
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super().__init__()
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decoder_state_input_c = keras.Input(shape=(latent_dim,))
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self.attn = nn.Linear(hid_dim * 3, hid_dim)
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decoder_states_inputs = [decoder_state_input_h, decoder_state_input_c]
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self.v = nn.Linear(hid_dim, 1, bias=False)
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decoder_lstm = model.layers[3]
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decoder_outputs, state_h_dec, state_c_dec = decoder_lstm(
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decoder_inputs, initial_state=decoder_states_inputs
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)
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decoder_states = [state_h_dec, state_c_dec]
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decoder_dense = model.layers[4]
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decoder_outputs = decoder_dense(decoder_outputs)
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decoder_model = keras.Model(
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[decoder_inputs] + decoder_states_inputs, [decoder_outputs] + decoder_states
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)
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def forward(self, hidden, encoder_outputs):
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reverse_input_char_index = dict((i, char) for char, i in input_token_index.items())
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# hidden = [batch size, hid dim]
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reverse_target_char_index = dict((i, char) for char, i in target_token_index.items())
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# encoder_outputs = [src len, batch size, hid dim * 2]
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src_len = encoder_outputs.shape[0]
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hidden = hidden.unsqueeze(1).expand(-1, src_len, -1)
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encoder_outputs = encoder_outputs.permute(1, 0, 2)
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# hidden = [batch size, src len, hid dim]
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# encoder_outputs = [batch size, src len, hid dim * 2]
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energy = torch.tanh(self.attn(torch.cat((hidden, encoder_outputs), dim=2)))
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# energy = [batch size, src len, hid dim]
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attention = self.v(energy).squeeze(2)
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# attention = [batch size, src len]
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return torch.softmax(attention, dim=1)
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class Decoder(nn.Module):
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def decode_sequences(input_seqs):
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def __init__(self, output_dim, emb_dim, hid_dim, n_layers, dropout, attention):
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states_values = encoder_model.predict(input_seqs, verbose=0)
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super().__init__()
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target_seqs = np.zeros((len(input_seqs), 1, num_decoder_tokens))
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self.output_dim = output_dim
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target_seqs[:, 0, target_token_index["\t"]] = 1.0
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self.attention = attention
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decoded_sentences = [""] * len(input_seqs)
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self.embedding = nn.Embedding(output_dim, emb_dim)
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stop_conditions = np.zeros(len(input_seqs), dtype=bool)
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self.rnn = nn.GRU(hid_dim * 2 + emb_dim, hid_dim, n_layers, dropout=dropout)
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self.fc_out = nn.Linear(hid_dim * 3 + emb_dim, output_dim)
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self.dropout = nn.Dropout(dropout)
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def forward(self, input, hidden, encoder_outputs):
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while not np.all(stop_conditions):
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input = input.unsqueeze(0)
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output_tokens, h, c = decoder_model.predict(
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embedded = self.dropout(self.embedding(input))
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[target_seqs] + states_values, verbose=0
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a = self.attention(hidden[-1], encoder_outputs).unsqueeze(1)
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)
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encoder_outputs = encoder_outputs.permute(1, 0, 2)
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weighted = torch.bmm(a, encoder_outputs)
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rnn_input = torch.cat((embedded, weighted.permute(1, 0, 2)), dim=2)
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output, hidden = self.rnn(rnn_input, hidden)
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embedded = embedded.squeeze(0)
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output = output.squeeze(0)
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weighted = weighted.squeeze(1)
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prediction = self.fc_out(torch.cat((output, weighted, embedded), dim=1))
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return prediction, hidden
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class Seq2Seq(nn.Module):
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sampled_token_indices = np.argmax(output_tokens[:, -1, :], axis=1)
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def __init__(self, encoder, decoder, device):
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sampled_chars = [
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super().__init__()
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reverse_target_char_index[idx] for idx in sampled_token_indices
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self.encoder = encoder
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]
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self.decoder = decoder
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self.device = device
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def forward(self, src, trg, teacher_forcing_ratio=0.5):
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for i, char in enumerate(sampled_chars):
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trg_len = trg.shape[0]
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decoded_sentences[i] += char
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batch_size = trg.shape[1]
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if char == "\n" or len(decoded_sentences[i]) > max_decoder_seq_length:
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trg_vocab_size = self.decoder.output_dim
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stop_conditions[i] = True
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outputs = torch.zeros(trg_len, batch_size, trg_vocab_size).to(self.device)
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encoder_outputs, hidden = self.encoder(src)
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# Initialize hidden state of the decoder with the hidden state of the encoder
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hidden = hidden.unsqueeze(0).repeat(self.decoder.rnn.num_layers, 1, 1)
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input = trg[0, :]
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for t in range(1, trg_len):
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output, hidden = self.decoder(input, hidden, encoder_outputs)
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outputs[t] = output
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top1 = output.argmax(1)
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input = trg[t] if random.random() < teacher_forcing_ratio else top1
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return outputs
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# Training and evaluation functions
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target_seqs = np.zeros((len(input_seqs), 1, num_decoder_tokens))
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def train(model, iterator, optimizer, criterion, clip, print_every=100, max_batches=1000):
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for i, token_index in enumerate(sampled_token_indices):
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model.train()
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target_seqs[i, 0, token_index] = 1.0
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epoch_loss = 0
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i = 0 # Initialize batch counter
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for src, trg in iterator:
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if i >= max_batches: # Limit the number of batches processed in each epoch
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break
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src = src.to(device)
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trg = trg.to(device)
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optimizer.zero_grad()
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output = model(src, trg)
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output_dim = output.shape[-1]
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output = output[1:].reshape(-1, output_dim)
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trg = trg[1:].reshape(-1)
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loss = criterion(output, trg)
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loss.backward()
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torch.nn.utils.clip_grad_norm_(model.parameters(), clip)
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optimizer.step()
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epoch_loss += loss.item()
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if (i + 1) % print_every == 0:
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states_values = [h, c]
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print(f'Batch {i+1}, Loss: {loss.item():.4f}')
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i += 1 # Increment batch counter
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return decoded_sentences
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return epoch_loss / (i if i > 0 else 1) # Avoid division by zero
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# BLEU score evaluation
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def calculate_bleu_score(input_texts, target_texts, num_samples=500):
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input_seqs = np.zeros(
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(num_samples, max_encoder_seq_length, num_encoder_tokens), dtype="float32"
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)
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for i, input_text in enumerate(input_texts[:num_samples]):
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for t, char in enumerate(input_text):
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input_seqs[i, t, input_token_index[char]] = 1.0
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input_seqs[i, t + 1 :, input_token_index[" "]] = 1.0
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def evaluate(model, iterator, criterion):
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decoded_sentences = decode_sequences(input_seqs)
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model.eval()
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epoch_loss = 0
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i = 0 # Initialize batch counter
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with torch.no_grad():
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for src, trg in iterator:
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src = src.to(device)
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trg = trg.to(device)
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output = model(src, trg, 0)
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output_dim = output.shape[-1]
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output = output[1:].reshape(-1, output_dim)
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trg = trg[1:].reshape(-1)
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loss = criterion(output, trg)
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epoch_loss += loss.item()
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i += 1 # Increment batch counter
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return epoch_loss / (i if i > 0 else 1) # Avoid division by zero
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# BLEU Score calculation
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references = [[list(text.strip())] for text in target_texts[:num_samples]]
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def calculate_bleu(data, model, src_vocab, trg_vocab):
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hypotheses = [list(text.strip()) for text in decoded_sentences]
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trgs = []
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bleu = corpus_bleu(references, hypotheses)
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pred_trgs = []
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print("BLEU Score:", bleu)
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for (src, trg) in data:
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src_tensor = torch.tensor([src_vocab.lookup(word) for word in src.split(' ')]).unsqueeze(1).to(device)
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trg_tensor = torch.tensor([trg_vocab.lookup(word) for word in trg.split(' ')]).unsqueeze(1).to(device)
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with torch.no_grad():
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output = model(src_tensor, trg_tensor, 0)
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output_dim = output.shape[-1]
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output = output[1:].reshape(-1, output_dim)
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output = output.argmax(1)
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pred_trg = [trg_vocab.index2word[idx.item()] for idx in output if idx.item() != trg_vocab.word2index['<pad>']]
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pred_trgs.append(pred_trg)
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trgs.append([trg.split(' ')])
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return bleu_score(pred_trgs, trgs)
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# Main script
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print("\nExample Translations:")
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INPUT_DIM = eng_vocab.n_words
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for i in range(10):
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OUTPUT_DIM = fra_vocab.n_words
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print("Input:", input_texts[i])
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ENC_EMB_DIM = 256
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print("Target:", target_texts[i])
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DEC_EMB_DIM = 256
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print("Translation:", decoded_sentences[i])
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HID_DIM = 512
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print()
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N_LAYERS = 2
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ENC_DROPOUT = 0.5
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DEC_DROPOUT = 0.5
|
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BATCH_SIZE = 32
|
|
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N_EPOCHS = 7
|
|
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CLIP = 1
|
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||||||
|
|
||||||
attn = Attention(HID_DIM)
|
calculate_bleu_score(input_texts, target_texts)
|
||||||
enc = Encoder(INPUT_DIM, ENC_EMB_DIM, HID_DIM, N_LAYERS, ENC_DROPOUT)
|
|
||||||
dec = Decoder(OUTPUT_DIM, DEC_EMB_DIM, HID_DIM, N_LAYERS, DEC_DROPOUT, attn)
|
|
||||||
|
|
||||||
model = Seq2Seq(enc, dec, device).to(device)
|
|
||||||
optimizer = optim.Adam(model.parameters())
|
|
||||||
criterion = nn.CrossEntropyLoss(ignore_index=fra_vocab.word2index['<pad>'])
|
|
||||||
|
|
||||||
# Splitting data into train and test sets
|
|
||||||
train_data = pairs[:int(0.8*len(pairs))]
|
|
||||||
test_data = pairs[int(0.8*len(pairs)):]
|
|
||||||
|
|
||||||
# Custom DataLoader with padding
|
|
||||||
def pad_sequence(seq, max_len, pad_value):
|
|
||||||
seq += [pad_value] * (max_len - len(seq))
|
|
||||||
return seq
|
|
||||||
|
|
||||||
def data_generator(data, src_vocab, trg_vocab, batch_size):
|
|
||||||
for i in range(0, len(data), batch_size):
|
|
||||||
src_batch = [d[0] for d in data[i:i+batch_size]]
|
|
||||||
trg_batch = [d[1] for d in data[i:i+batch_size]]
|
|
||||||
max_src_len = max(len(s.split(' ')) for s in src_batch)
|
|
||||||
max_trg_len = max(len(s.split(' ')) for s in trg_batch)
|
|
||||||
src_tensor = torch.tensor([pad_sequence([src_vocab.lookup(word) for word in sentence.split(' ')], max_len=max_src_len, pad_value=src_vocab.word2index['<pad>']) for sentence in src_batch], dtype=torch.long).T
|
|
||||||
trg_tensor = torch.tensor([pad_sequence([trg_vocab.lookup(word) for word in sentence.split(' ')], max_len=max_trg_len, pad_value=trg_vocab.word2index['<pad>']) for sentence in trg_batch], dtype=torch.long).T
|
|
||||||
yield src_tensor, trg_tensor
|
|
||||||
|
|
||||||
for epoch in range(N_EPOCHS):
|
|
||||||
print(f'Epoch {epoch+1}/{N_EPOCHS}')
|
|
||||||
train_iterator = data_generator(train_data, eng_vocab, fra_vocab, BATCH_SIZE)
|
|
||||||
valid_iterator = data_generator(test_data, eng_vocab, fra_vocab, BATCH_SIZE)
|
|
||||||
train_loss = train(model, train_iterator, optimizer, criterion, CLIP)
|
|
||||||
valid_loss = evaluate(model, valid_iterator, criterion)
|
|
||||||
print(f'Epoch {epoch+1:02}, Train Loss: {train_loss:.3f}, Val. Loss: {valid_loss:.3f}')
|
|
||||||
|
|
||||||
bleu = calculate_bleu(test_data, model, eng_vocab, fra_vocab)
|
|
||||||
print(f'BLEU score = {bleu:.2f}')
|
|
||||||
|
Loading…
Reference in New Issue
Block a user