使用seq2seq架构实现英译法(一)+https://developer.aliyun.com/article/1544783?spm=a2c6h.13148508.setting.29.22454f0eHFZZj3
构建编码器和解码器
构建基于GRU的编码器
- “embedding”指的是一个将离散变量(如单词、符号等)转换为连续向量表示的过程或技术
- “embedded”是embedding过程的输出,即已经通过嵌入矩阵转换后的连续向量。在神经网络中,这些向量将作为后续层的输入。
class EncoderRNN(nn.Module): def __init__(self, input_size, hidden_size): super(EncoderRNN, self).__init__() self.hidden_size = hidden_size self.embedding = nn.Embedding(input_size, hidden_size) self.gru = nn.GRU(hidden_size, hidden_size) def forward(self, input, hidden): output = self.embedding(input).view(1, 1, -1) output, hidden = self.gru(output, hidden) return output, hidden def initHidden(self): return torch.zeros(1, 1, self.hidden_size, device=device)
- 测试:参数:
hidden_size = 25 input_size = 20 的第一个词 input = pair_tensor[0][0] hidden = torch.zeros(1, 1, hidden_size) encoder = EncoderRNN(input_size, hidden_size) encoder_output, hidden = encoder(input, hidden) print(encoder_output) tensor([[[ 1.9149e-01, -2.0070e-01, -8.3882e-02, -3.3037e-02, -1.3491e-01, -8.8831e-02, -1.6626e-01, -1.9346e-01, -4.3996e-01, 1.8020e-02, 2.8854e-02, 2.2310e-01, 3.5153e-01, 2.9635e-01, 1.5030e-01, -8.5266e-02, -1.4909e-01, 2.4336e-04, -2.3522e-01, 1.1359e-01, 1.6439e-01, 1.4872e-01, -6.1619e-02, -1.0807e-02, 1.1216e-02]]], grad_fn=<StackBackward>)
构建基于GRU的解码器
class DecoderRNN(nn.Module): def __init__(self, hidden_size, output_size): super(DecoderRNN, self).__init__() self.hidden_size = hidden_size self.embedding = nn.Embedding(output_size, hidden_size) self.gru = nn.GRU(hidden_size, hidden_size) self.out = nn.Linear(hidden_size, output_size) self.softmax = nn.LogSoftmax(dim=1) def forward(self, input, hidden): output = self.embedding(input).view(1, 1, -1) output = F.relu(output) output, hidden = self.gru(output, hidden) output = self.softmax(self.out(output[0])) return output, hidden def initHidden(self): return torch.zeros(1, 1, self.hidden_size, device=device)
构建基于GRU和Attention的解码器💥
💥三个输入:
- prev_hidden:指上一个时间步解码器的隐藏状态
- input:input 是当前时间步解码器的输入。在解码的开始阶段,它可能是一个特殊的起始符号。在随后的解码步骤中,input 通常是上一个时间步解码器输出的词(或对应的词向量)。
- encoder_outputs :是编码器处理输入序列后生成的一系列输出向量,在基于Attention的解码器中,这些输出向量将作为注意力机制的候选记忆单元,用于计算当前解码步与输入序列中不同位置的相关性。
class AttnDecoderRNN(nn.Module): def __init__(self, hidden_size, output_size, dropout_p=0.1, max_length=MAX_LENGTH): super(AttnDecoderRNN, self).__init__() self.hidden_size = hidden_size self.output_size = output_size self.dropout_p = dropout_p self.max_length = max_length self.embedding = nn.Embedding(self.output_size, self.hidden_size) self.attn = nn.Linear(self.hidden_size * 2, self.max_length) self.attn_combine = nn.Linear(self.hidden_size * 2, self.hidden_size) self.dropout = nn.Dropout(self.dropout_p) self.gru = nn.GRU(self.hidden_size, self.hidden_size) self.out = nn.Linear(self.hidden_size, self.output_size) def forward(self, input, hidden, encoder_outputs): embedded = self.embedding(input).view(1, 1, -1) embedded = self.dropout(embedded) attn_weights = F.softmax( self.attn(torch.cat((embedded[0], hidden[0]), 1)), dim=1) attn_applied = torch.bmm(attn_weights.unsqueeze(0), encoder_outputs.unsqueeze(0)) output = torch.cat((embedded[0], attn_applied[0]), 1) output = self.attn_combine(output).unsqueeze(0) output = F.relu(output) output, hidden = self.gru(output, hidden) output = F.log_softmax(self.out(output[0]), dim=1) return output, hidden, attn_weights def initHidden(self): return torch.zeros(1, 1, self.hidden_size, device=device)
构建模型训练函数
teacher_forcing介绍
Teacher Forcing是一种在训练序列生成模型,特别是循环神经网络(RNN)和序列到序列(seq2seq)模型时常用的技术。在seq2seq架构中,根据循环神经网络理论,解码器每次应该使用上一步的结果作为输入的一部分, 但是训练过程中,一旦上一步的结果是错误的,就会导致这种错误被累积,无法达到训练效果,我们需要一种机制改变上一步出错的情况,因为训练时我们是已知正确的输出应该是什么,因此可以强制将上一步结果设置成正确的输出, 这种方式就叫做teacher_forcing。
teacher_forcing的作用
- 加速模型收敛与稳定训练:通过使用真实的历史数据作为解码器的输入,Teacher Forcing技术可以加速模型的收敛速度,并使得训练过程更加稳定,因为它避免了因模型早期预测错误而导致的累积误差。
- 矫正预测并避免误差放大:Teacher Forcing在训练时能够矫正模型的预测,防止在序列生成过程中误差的进一步放大,从而提高了模型的预测准确性。
teacher_forcing_ratio = 0.5 def train(input_tensor, target_tensor, encoder, decoder, encoder_optimizer, decoder_optimizer, criterion, max_length=MAX_LENGTH): encoder_hidden = encoder.initHidden() encoder_optimizer.zero_grad() decoder_optimizer.zero_grad() input_length = input_tensor.size(0) target_length = target_tensor.size(0) encoder_outputs = torch.zeros(max_length, encoder.hidden_size, device=device) loss = 0 for ei in range(input_length): encoder_output, encoder_hidden = encoder( input_tensor[ei], encoder_hidden) encoder_outputs[ei] = encoder_output[0, 0] decoder_input = torch.tensor([[SOS_token]], device=device) decoder_hidden = encoder_hidden use_teacher_forcing = True if random.random() < teacher_forcing_ratio else False if use_teacher_forcing: for di in range(target_length): decoder_output, decoder_hidden, decoder_attention = decoder( decoder_input, decoder_hidden, encoder_outputs) loss += criterion(decoder_output, target_tensor[di]) decoder_input = target_tensor[di] else: for di in range(target_length): decoder_output, decoder_hidden, decoder_attention = decoder( decoder_input, decoder_hidden, encoder_outputs) topv, topi = decoder_output.topk(1) loss += criterion(decoder_output, target_tensor[di]) if topi.squeeze().item() == EOS_token: break decoder_input = topi.squeeze().detach() loss.backward() encoder_optimizer.step() decoder_optimizer.step() return loss.item() / target_length
构建时间计算函数
import time import math def timeSince(since): now = time.time() s = now - since m = math.floor(s / 60) s -= m * 60 return '%dm %ds' % (m, s)
调用训练函数并打印日志和制图
import matplotlib.pyplot as plt def trainIters(encoder, decoder, n_iters, print_every=1000, plot_every=100, learning_rate=0.01): start = time.time() plot_losses = [] print_loss_total = 0 plot_loss_total = 0 encoder_optimizer = optim.SGD(encoder.parameters(), lr=learning_rate) decoder_optimizer = optim.SGD(decoder.parameters(), lr=learning_rate) criterion = nn.NLLLoss() for iter in range(1, n_iters + 1): training_pair = tensorsFromPair(random.choice(pairs)) input_tensor = training_pair[0] target_tensor = training_pair[1] loss = train(input_tensor, target_tensor, encoder, decoder, encoder_optimizer, decoder_optimizer, criterion) print_loss_total += loss plot_loss_total += loss if iter % print_every == 0: print_loss_avg = print_loss_total / print_every print_loss_total = 0 print('%s (%d %d%%) %.4f' % (timeSince(start), iter, iter / n_iters * 100, print_loss_avg)) if iter % plot_every == 0: plot_loss_avg = plot_loss_total / plot_every plot_losses.append(plot_loss_avg) plot_loss_total = 0 plt.figure() plt.plot(plot_losses) plt.savefig("loss.png")
💥训练模型:
hidden_size = 256 encoder1 = EncoderRNN(input_lang.n_words, hidden_size).to(device) attn_decoder1 = AttnDecoderRNN(hidden_size, output_lang.n_words, dropout_p=0.1).to(device) n_iters = 80000 print_every = 5000 trainIters(encoder1, attn_decoder1, n_iters, print_every=print_every)
模型会不断打印loss损失值并且绘制图像
- 一直下降的损失曲线, 说明模型正在收敛
构建模型评估函数
def evaluate(encoder, decoder, sentence, max_length=MAX_LENGTH): with torch.no_grad(): input_tensor = tensorFromSentence(input_lang, sentence) input_length = input_tensor.size()[0] encoder_hidden = encoder.initHidden() encoder_outputs = torch.zeros(max_length, encoder.hidden_size, device=device) for ei in range(input_length): encoder_output, encoder_hidden = encoder(input_tensor[ei], encoder_hidden) encoder_outputs[ei] += encoder_output[0, 0] decoder_input = torch.tensor([[SOS_token]], device=device) decoder_hidden = encoder_hidden decoded_words = [] decoder_attentions = torch.zeros(max_length, max_length) for di in range(max_length): decoder_output, decoder_hidden, decoder_attention = decoder( decoder_input, decoder_hidden, encoder_outputs) decoder_attentions[di] = decoder_attention.data topv, topi = decoder_output.data.topk(1) if topi.item() == EOS_token: decoded_words.append('<EOS>') break else: decoded_words.append(output_lang.index2word[topi.item()]) decoder_input = topi.squeeze().detach() return decoded_words, decoder_attentions[:di + 1]
随机选择指定数量的数据进行评估
def evaluateRandomly(encoder, decoder, n=6): for i in range(n): pair = random.choice(pairs) print('>', pair[0]) print('=', pair[1]) output_words, attentions = evaluate(encoder, decoder, pair[0]) output_sentence = ' '.join(output_words) print('<', output_sentence) print('') evaluateRandomly(encoder1, attn_decoder1)
效果:
> i m impressed with your french . = je suis impressionne par votre francais . < je suis impressionnee par votre francais . <EOS> > i m more than a friend . = je suis plus qu une amie . < je suis plus qu une amie . <EOS> > she is beautiful like her mother . = elle est belle comme sa mere . < elle est sa sa mere . <EOS> > you re winning aren t you ? = vous gagnez n est ce pas ? < tu restez n est ce pas ? <EOS> > he is angry with you . = il est en colere apres toi . < il est en colere apres toi . <EOS> > you re very timid . = vous etes tres craintifs . < tu es tres craintive . <EOS>
Attention张量制图
sentence = "we re both teachers ." output_words, attentions = evaluate( encoder1, attn_decoder1, sentence) print(output_words) plt.matshow(attentions.numpy()) plt.savefig("attn.png")
如果迭代次数过少,训练不充分,那么注意力就不会很好:
💯迭代次数变大:
