challenging-america-word-ga.../bigram-neural/train2.py

import pickle

from torch.utils.data import IterableDataset
import itertools
from torch import nn
import torch
import lzma
from torch.utils.data import DataLoader

import tqdm

vocabulary_size = 20000

vocab = None
with open('vocabulary.pickle', 'rb') as handle:
    vocab = pickle.load(handle)

def look_ahead_iterator(gen):
   prev = None
   for item in gen:
      if prev is not None:
         yield (prev, item)
      prev = item

def get_words_from_line(line):
  line = line.rstrip()
  yield '<s>'
  for t in line.split(' '):
     yield t
  yield '</s>'

def get_word_lines_from_file(file_name):
  with lzma.open(file_name, 'r') as fh:
    for line in fh:
       yield get_words_from_line(line.decode('utf-8'))

class Bigrams(IterableDataset):
  def __init__(self, text_file, vocabulary_size):
      self.vocab = vocab
      self.vocab.set_default_index(self.vocab['<unk>'])
      self.vocabulary_size = vocabulary_size
      self.text_file = text_file

  def __iter__(self):
     return look_ahead_iterator(
         (self.vocab[t] for t in itertools.chain.from_iterable(get_word_lines_from_file(self.text_file))))

train_dataset = Bigrams('train/in.tsv.xz', vocabulary_size)

# print(next(iter(train_dataset)))
# 
# print(vocab.lookup_tokens([23, 0]))

embed_size = 100

class SimpleBigramNeuralLanguageModel(nn.Module):
  def __init__(self, vocabulary_size, embedding_size):
      super(SimpleBigramNeuralLanguageModel, self).__init__()
      self.model = nn.Sequential(
          nn.Embedding(vocabulary_size, embedding_size),
          nn.Linear(embedding_size, vocabulary_size),
          nn.Softmax()
      )

  def forward(self, x):
      return self.model(x)

device = 'cuda'
model = SimpleBigramNeuralLanguageModel(vocabulary_size, embed_size).to(device)
data = DataLoader(train_dataset, batch_size=500)
optimizer = torch.optim.Adam(model.parameters())
criterion = torch.nn.NLLLoss()

model.train()
step = 0
for x, y in tqdm.tqdm(data):
   x = x.to(device)
   y = y.to(device)
   optimizer.zero_grad()
   ypredicted = model(x)
   loss = criterion(torch.log(ypredicted), y)
   if step % 100 == 0:
      print(step, loss)
   if step > 5000:
       break
   step += 1
   loss.backward()
   optimizer.step()

torch.save(model.state_dict(), 'model1.bin')

device = 'cuda'
model = SimpleBigramNeuralLanguageModel(vocabulary_size, embed_size).to(device)
model.load_state_dict(torch.load('model1.bin'))
model.eval()

ixs = torch.tensor(vocab.forward(['that'])).to(device)

out = model(ixs)
top = torch.topk(out[0], 10)
top_indices = top.indices.tolist()
top_probs = top.values.tolist()
top_words = vocab.lookup_tokens(top_indices)
print(list(zip(top_words, top_indices, top_probs)))
bigram neural 2023-04-26 15:00:18 +02:00			`import pickle`

			`from torch.utils.data import IterableDataset`
			`import itertools`
			`from torch import nn`
			`import torch`
			`import lzma`
			`from torch.utils.data import DataLoader`

			`import tqdm`

			`vocabulary_size = 20000`

			`vocab = None`
			`with open('vocabulary.pickle', 'rb') as handle:`
			`vocab = pickle.load(handle)`

			`def look_ahead_iterator(gen):`
			`prev = None`
			`for item in gen:`
			`if prev is not None:`
			`yield (prev, item)`
			`prev = item`

			`def get_words_from_line(line):`
			`line = line.rstrip()`
			`yield '<s>'`
			`for t in line.split(' '):`
			`yield t`
			`yield '</s>'`

			`def get_word_lines_from_file(file_name):`
			`with lzma.open(file_name, 'r') as fh:`
			`for line in fh:`
			`yield get_words_from_line(line.decode('utf-8'))`

			`class Bigrams(IterableDataset):`
			`def __init__(self, text_file, vocabulary_size):`
			`self.vocab = vocab`
			`self.vocab.set_default_index(self.vocab['<unk>'])`
			`self.vocabulary_size = vocabulary_size`
			`self.text_file = text_file`

			`def __iter__(self):`
			`return look_ahead_iterator(`
			`(self.vocab[t] for t in itertools.chain.from_iterable(get_word_lines_from_file(self.text_file))))`

			`train_dataset = Bigrams('train/in.tsv.xz', vocabulary_size)`

			`# print(next(iter(train_dataset)))`
			`#`
			`# print(vocab.lookup_tokens([23, 0]))`

			`embed_size = 100`

			`class SimpleBigramNeuralLanguageModel(nn.Module):`
			`def __init__(self, vocabulary_size, embedding_size):`
			`super(SimpleBigramNeuralLanguageModel, self).__init__()`
			`self.model = nn.Sequential(`
			`nn.Embedding(vocabulary_size, embedding_size),`
			`nn.Linear(embedding_size, vocabulary_size),`
			`nn.Softmax()`
			`)`

			`def forward(self, x):`
			`return self.model(x)`

			`device = 'cuda'`
			`model = SimpleBigramNeuralLanguageModel(vocabulary_size, embed_size).to(device)`
			`data = DataLoader(train_dataset, batch_size=500)`
			`optimizer = torch.optim.Adam(model.parameters())`
			`criterion = torch.nn.NLLLoss()`

			`model.train()`
			`step = 0`
			`for x, y in tqdm.tqdm(data):`
			`x = x.to(device)`
			`y = y.to(device)`
			`optimizer.zero_grad()`
			`ypredicted = model(x)`
			`loss = criterion(torch.log(ypredicted), y)`
			`if step % 100 == 0:`
			`print(step, loss)`
			`if step > 5000:`
			`break`
			`step += 1`
			`loss.backward()`
			`optimizer.step()`

			`torch.save(model.state_dict(), 'model1.bin')`

			`device = 'cuda'`
			`model = SimpleBigramNeuralLanguageModel(vocabulary_size, embed_size).to(device)`
			`model.load_state_dict(torch.load('model1.bin'))`
			`model.eval()`

			`ixs = torch.tensor(vocab.forward(['that'])).to(device)`

			`out = model(ixs)`
			`top = torch.topk(out[0], 10)`
			`top_indices = top.indices.tolist()`
			`top_probs = top.values.tolist()`
			`top_words = vocab.lookup_tokens(top_indices)`
			`print(list(zip(top_words, top_indices, top_probs)))`