removed bilstm

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William Falcon 2019-04-03 12:55:45 -04:00
parent 18eaa59c28
commit 64827b7029
2 changed files with 0 additions and 167 deletions

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@ -1,167 +0,0 @@
import torch.nn as nn
import numpy as np
from test_tube import HyperOptArgumentParser
import torch
from torch.autograd import Variable
from sklearn.metrics import confusion_matrix, f1_score
from torch.nn import functional as F
class BiLSTMPack(nn.Module):
"""
Sample model to show how to define a template
"""
def __init__(self, hparams):
# init superclass
super(BiLSTMPack, self).__init__(hparams)
self.hidden = None
# trigger tag building
self.ner_tagset = {'O': 0, 'I-Bio': 1}
self.nb_tags = len(self.ner_tagset)
# build model
print('building model...')
if hparams.model_load_weights_path is None:
self.__build_model()
print('model built')
else:
self = BiLSTMPack.load(hparams.model_load_weights_path, hparams.on_gpu, hparams)
print('model loaded from: {}'.format(hparams.model_load_weights_path))
def __build_model(self):
"""
Layout model
:return:
"""
# design the number of final units
self.output_dim = self.hparams.nb_lstm_units
# when it's bidirectional our weights double
if self.hparams.bidirectional:
self.output_dim *= 2
# total number of words
total_words = len(self.tng_dataloader.dataset.words_token_to_idx)
# word embeddings
self.word_embedding = nn.Embedding(
num_embeddings=total_words + 1,
embedding_dim=self.hparams.embedding_dim,
padding_idx=0
)
# design the LSTM
self.lstm = nn.LSTM(
self.hparams.embedding_dim,
self.hparams.nb_lstm_units,
num_layers=self.hparams.nb_lstm_layers,
bidirectional=self.hparams.bidirectional,
dropout=self.hparams.drop_prob,
batch_first=True,
)
# map to tag space
self.fc_out = nn.Linear(self.output_dim, self.out_dim)
self.hidden_to_tag = nn.Linear(self.output_dim, self.nb_tags)
def init_hidden(self, batch_size):
# the weights are of the form (nb_layers * 2 if bidirectional, batch_size, nb_lstm_units)
mult = 2 if self.hparams.bidirectional else 1
hidden_a = torch.randn(self.hparams.nb_layers * mult, batch_size, self.nb_rnn_units)
hidden_b = torch.randn(self.hparams.nb_layers * mult, batch_size, self.nb_rnn_units)
if self.hparams.on_gpu:
hidden_a = hidden_a.cuda()
hidden_b = hidden_b.cuda()
hidden_a = Variable(hidden_a)
hidden_b = Variable(hidden_b)
return (hidden_a, hidden_b)
def forward(self, model_in):
# layout data (expand it, etc...)
# x = sequences
x, seq_lengths = model_in
batch_size, seq_len = x.size()
# reset RNN hidden state
self.hidden = self.init_hidden(batch_size)
# embed
x = self.word_embedding(x)
# run through rnn using packed sequences
x = torch.nn.utils.rnn.pack_padded_sequence(x, seq_lengths, batch_first=True)
x, self.hidden = self.lstm(x, self.hidden)
x, _ = torch.nn.utils.rnn.pad_packed_sequence(x, batch_first=True)
# if asked for only last state, use the h_n which is the same as out(t=n)
if not self.return_sequence:
# pull out hidden states
# h_n = (nb_directions * nb_layers, batch_size, emb_size)
nb_directions = 2 if self.bidirectional else 1
(h_n, _) = self.hidden
# reshape to make indexing easier
# forward = 0, backward = 1 (of nb_directions)
h_n = h_n.view(self.nb_layers, nb_directions, batch_size, self.nb_rnn_units)
# pull out last forward
forward_h_n = h_n[-1, 0, :, :]
x = forward_h_n
# if bidirectional, also pull out the last hidden of backward network
if self.bidirectional:
backward_h_n = h_n[-1, 1, :, :]
x = torch.cat([forward_h_n, backward_h_n], dim=1)
# project to tag space
x = x.contiguous()
x = x.view(-1, self.output_dim)
x = self.hidden_to_tag(x)
return x
def loss(self, model_out):
# cross entropy loss
logits, y = model_out
y, y_lens = y
# flatten y and logits
y = y.view(-1)
logits = logits.view(-1, self.nb_tags)
# calculate a mask to remove padding tokens
mask = (y >= 0).float()
# count how many tokens we have
num_tokens = int(torch.sum(mask).data[0])
# pick the correct values and mask out
logits = logits[range(logits.shape[0]), y] * mask
# compute the ce loss
ce_loss = -torch.sum(logits)/num_tokens
return ce_loss
def pull_out_last_embedding(self, x, seq_lengths, batch_size, on_gpu):
# grab only the last activations from the non-padded ouput
x_last = torch.zeros([batch_size, 1, x.size(-1)])
for i, seq_len in enumerate(seq_lengths):
x_last[i, :, :] = x[i, seq_len-1, :]
# put on gpu when requested
if on_gpu:
x_last = x_last.cuda()
# turn into torch var
x_last = Variable(x_last)
return x_last