# %% # code by Tae Hwan Jung(Jeff Jung) @graykode # Reference : https://github.com/jadore801120/attention-is-all-you-need-pytorch # https://github.com/JayParks/transformer, https://github.com/dhlee347/pytorchic-bert import math import re from random import * import numpy as np import torch import torch.nn as nn import torch.optim as optim # sample IsNext and NotNext to be same in small batch size def make_batch(): batch = [] positive = negative = 0 while positive != batch_size/2 or negative != batch_size/2: tokens_a_index, tokens_b_index= randrange(len(sentences)), randrange(len(sentences)) # sample random index in sentences tokens_a, tokens_b= token_list[tokens_a_index], token_list[tokens_b_index] input_ids = [word_dict['[CLS]']] + tokens_a + [word_dict['[SEP]']] + tokens_b + [word_dict['[SEP]']] segment_ids = [0] * (1 + len(tokens_a) + 1) + [1] * (len(tokens_b) + 1) # MASK LM n_pred = min(max_pred, max(1, int(round(len(input_ids) * 0.15)))) # 15 % of tokens in one sentence cand_maked_pos = [i for i, token in enumerate(input_ids) if token != word_dict['[CLS]'] and token != word_dict['[SEP]']] shuffle(cand_maked_pos) masked_tokens, masked_pos = [], [] for pos in cand_maked_pos[:n_pred]: masked_pos.append(pos) masked_tokens.append(input_ids[pos]) if random() < 0.8: # 80% input_ids[pos] = word_dict['[MASK]'] # make mask elif random() < 0.5: # 10% index = randint(0, vocab_size - 1) # random index in vocabulary input_ids[pos] = word_dict[number_dict[index]] # replace # Zero Paddings n_pad = maxlen - len(input_ids) input_ids.extend([0] * n_pad) segment_ids.extend([0] * n_pad) # Zero Padding (100% - 15%) tokens if max_pred > n_pred: n_pad = max_pred - n_pred masked_tokens.extend([0] * n_pad) masked_pos.extend([0] * n_pad) if tokens_a_index + 1 == tokens_b_index and positive < batch_size/2: batch.append([input_ids, segment_ids, masked_tokens, masked_pos, True]) # IsNext positive += 1 elif tokens_a_index + 1 != tokens_b_index and negative < batch_size/2: batch.append([input_ids, segment_ids, masked_tokens, masked_pos, False]) # NotNext negative += 1 return batch # Proprecessing Finished def get_attn_pad_mask(seq_q, seq_k): batch_size, len_q = seq_q.size() batch_size, len_k = seq_k.size() # eq(zero) is PAD token pad_attn_mask = seq_k.data.eq(0).unsqueeze(1) # batch_size x 1 x len_k(=len_q), one is masking return pad_attn_mask.expand(batch_size, len_q, len_k) # batch_size x len_q x len_k def gelu(x): "Implementation of the gelu activation function by Hugging Face" return x * 0.5 * (1.0 + torch.erf(x / math.sqrt(2.0))) class Embedding(nn.Module): def __init__(self): super(Embedding, self).__init__() self.tok_embed = nn.Embedding(vocab_size, d_model) # token embedding self.pos_embed = nn.Embedding(maxlen, d_model) # position embedding self.seg_embed = nn.Embedding(n_segments, d_model) # segment(token type) embedding self.norm = nn.LayerNorm(d_model) def forward(self, x, seg): seq_len = x.size(1) pos = torch.arange(seq_len, dtype=torch.long) pos = pos.unsqueeze(0).expand_as(x) # (seq_len,) -> (batch_size, seq_len) embedding = self.tok_embed(x) + self.pos_embed(pos) + self.seg_embed(seg) return self.norm(embedding) class ScaledDotProductAttention(nn.Module): def __init__(self): super(ScaledDotProductAttention, self).__init__() def forward(self, Q, K, V, attn_mask): scores = torch.matmul(Q, K.transpose(-1, -2)) / np.sqrt(d_k) # scores : [batch_size x n_heads x len_q(=len_k) x len_k(=len_q)] scores.masked_fill_(attn_mask, -1e9) # Fills elements of self tensor with value where mask is one. attn = nn.Softmax(dim=-1)(scores) context = torch.matmul(attn, V) return context, attn class MultiHeadAttention(nn.Module): def __init__(self): super(MultiHeadAttention, self).__init__() self.W_Q = nn.Linear(d_model, d_k * n_heads) self.W_K = nn.Linear(d_model, d_k * n_heads) self.W_V = nn.Linear(d_model, d_v * n_heads) def forward(self, Q, K, V, attn_mask): # q: [batch_size x len_q x d_model], k: [batch_size x len_k x d_model], v: [batch_size x len_k x d_model] residual, batch_size = Q, Q.size(0) # (B, S, D) -proj-> (B, S, D) -split-> (B, S, H, W) -trans-> (B, H, S, W) q_s = self.W_Q(Q).view(batch_size, -1, n_heads, d_k).transpose(1,2) # q_s: [batch_size x n_heads x len_q x d_k] k_s = self.W_K(K).view(batch_size, -1, n_heads, d_k).transpose(1,2) # k_s: [batch_size x n_heads x len_k x d_k] v_s = self.W_V(V).view(batch_size, -1, n_heads, d_v).transpose(1,2) # v_s: [batch_size x n_heads x len_k x d_v] attn_mask = attn_mask.unsqueeze(1).repeat(1, n_heads, 1, 1) # attn_mask : [batch_size x n_heads x len_q x len_k] # context: [batch_size x n_heads x len_q x d_v], attn: [batch_size x n_heads x len_q(=len_k) x len_k(=len_q)] context, attn = ScaledDotProductAttention()(q_s, k_s, v_s, attn_mask) context = context.transpose(1, 2).contiguous().view(batch_size, -1, n_heads * d_v) # context: [batch_size x len_q x n_heads * d_v] output = nn.Linear(n_heads * d_v, d_model)(context) return nn.LayerNorm(d_model)(output + residual), attn # output: [batch_size x len_q x d_model] class PoswiseFeedForwardNet(nn.Module): def __init__(self): super(PoswiseFeedForwardNet, self).__init__() self.fc1 = nn.Linear(d_model, d_ff) self.fc2 = nn.Linear(d_ff, d_model) def forward(self, x): # (batch_size, len_seq, d_model) -> (batch_size, len_seq, d_ff) -> (batch_size, len_seq, d_model) return self.fc2(gelu(self.fc1(x))) class EncoderLayer(nn.Module): def __init__(self): super(EncoderLayer, self).__init__() self.enc_self_attn = MultiHeadAttention() self.pos_ffn = PoswiseFeedForwardNet() def forward(self, enc_inputs, enc_self_attn_mask): enc_outputs, attn = self.enc_self_attn(enc_inputs, enc_inputs, enc_inputs, enc_self_attn_mask) # enc_inputs to same Q,K,V enc_outputs = self.pos_ffn(enc_outputs) # enc_outputs: [batch_size x len_q x d_model] return enc_outputs, attn class BERT(nn.Module): def __init__(self): super(BERT, self).__init__() self.embedding = Embedding() self.layers = nn.ModuleList([EncoderLayer() for _ in range(n_layers)]) self.fc = nn.Linear(d_model, d_model) self.activ1 = nn.Tanh() self.linear = nn.Linear(d_model, d_model) self.activ2 = gelu self.norm = nn.LayerNorm(d_model) self.classifier = nn.Linear(d_model, 2) # decoder is shared with embedding layer embed_weight = self.embedding.tok_embed.weight n_vocab, n_dim = embed_weight.size() self.decoder = nn.Linear(n_dim, n_vocab, bias=False) self.decoder.weight = embed_weight self.decoder_bias = nn.Parameter(torch.zeros(n_vocab)) def forward(self, input_ids, segment_ids, masked_pos): output = self.embedding(input_ids, segment_ids) enc_self_attn_mask = get_attn_pad_mask(input_ids, input_ids) for layer in self.layers: output, enc_self_attn = layer(output, enc_self_attn_mask) # output : [batch_size, len, d_model], attn : [batch_size, n_heads, d_mode, d_model] # it will be decided by first token(CLS) h_pooled = self.activ1(self.fc(output[:, 0])) # [batch_size, d_model] logits_clsf = self.classifier(h_pooled) # [batch_size, 2] masked_pos = masked_pos[:, :, None].expand(-1, -1, output.size(-1)) # [batch_size, max_pred, d_model] # get masked position from final output of transformer. h_masked = torch.gather(output, 1, masked_pos) # masking position [batch_size, max_pred, d_model] h_masked = self.norm(self.activ2(self.linear(h_masked))) logits_lm = self.decoder(h_masked) + self.decoder_bias # [batch_size, max_pred, n_vocab] return logits_lm, logits_clsf if __name__ == '__main__': # BERT Parameters maxlen = 30 # maximum of length batch_size = 6 max_pred = 5 # max tokens of prediction n_layers = 6 # number of Encoder of Encoder Layer n_heads = 12 # number of heads in Multi-Head Attention d_model = 768 # Embedding Size d_ff = 768 * 4 # 4*d_model, FeedForward dimension d_k = d_v = 64 # dimension of K(=Q), V n_segments = 2 text = ( 'Hello, how are you? I am Romeo.\n' 'Hello, Romeo My name is Juliet. Nice to meet you.\n' 'Nice meet you too. How are you today?\n' 'Great. My baseball team won the competition.\n' 'Oh Congratulations, Juliet\n' 'Thanks you Romeo' ) sentences = re.sub("[.,!?\\-]", '', text.lower()).split('\n') # filter '.', ',', '?', '!' word_list = list(set(" ".join(sentences).split())) word_dict = {'[PAD]': 0, '[CLS]': 1, '[SEP]': 2, '[MASK]': 3} for i, w in enumerate(word_list): word_dict[w] = i + 4 number_dict = {i: w for i, w in enumerate(word_dict)} vocab_size = len(word_dict) token_list = list() for sentence in sentences: arr = [word_dict[s] for s in sentence.split()] token_list.append(arr) model = BERT() criterion = nn.CrossEntropyLoss() optimizer = optim.Adam(model.parameters(), lr=0.001) batch = make_batch() input_ids, segment_ids, masked_tokens, masked_pos, isNext = map(torch.LongTensor, zip(*batch)) for epoch in range(100): optimizer.zero_grad() logits_lm, logits_clsf = model(input_ids, segment_ids, masked_pos) loss_lm = criterion(logits_lm.transpose(1, 2), masked_tokens) # for masked LM loss_lm = (loss_lm.float()).mean() loss_clsf = criterion(logits_clsf, isNext) # for sentence classification loss = loss_lm + loss_clsf if (epoch + 1) % 10 == 0: print('Epoch:', '%04d' % (epoch + 1), 'cost =', '{:.6f}'.format(loss)) loss.backward() optimizer.step() # Predict mask tokens ans isNext input_ids, segment_ids, masked_tokens, masked_pos, isNext = map(torch.LongTensor, zip(batch[0])) print(text) print([number_dict[w.item()] for w in input_ids[0] if number_dict[w.item()] != '[PAD]']) logits_lm, logits_clsf = model(input_ids, segment_ids, masked_pos) logits_lm = logits_lm.data.max(2)[1][0].data.numpy() print('masked tokens list : ',[pos.item() for pos in masked_tokens[0] if pos.item() != 0]) print('predict masked tokens list : ',[pos for pos in logits_lm if pos != 0]) logits_clsf = logits_clsf.data.max(1)[1].data.numpy()[0] print('isNext : ', True if isNext else False) print('predict isNext : ',True if logits_clsf else False)