Add two sided GRU + results

2023-09-25 12:14:32 +02:00 · 2023-09-25 12:14:32 +02:00 · 22b9d58cd7
commit 22b9d58cd7
parent b5e4119265
3 changed files with 18224 additions and 17933 deletions
--- a/dev-0/out.tsv
+++ b/dev-0/out.tsv
--- a/run-gru.py
+++ b/run-gru.py
@ -0,0 +1,291 @@
 #!/usr/bin/env python
 # coding: utf-8
 # In[1]:
 from collections import Counter
 import torch
 from torch.utils.data import Dataset
 device = torch.device("cuda")
 # In[2]:
 import lzma
 def read_xz_file(fname):
    with lzma.open(fname, mode='rt', encoding='utf-8') as f:
        return [line.strip() for line in f.readlines()]
 def read_file(fname):
    with open(fname, mode='rt', encoding='utf-8') as f:
        return [line.strip() for line in f.readlines()]
 def get_contexts(input_text):
    all_fields = input_text.replace(r'\n', ' ').split('\t')
    return {'left': all_fields[6], 'right': all_fields[7]}
 def compose_sentences(raw_input, labels) -> list[dict[str, str]]:
    result = []
    for input, label in zip(raw_input, labels):
        context = get_contexts(input)
        result.append(f'{context["left"]} {input} {context["right"]}')
    return result
 # In[3]:
 train_input_raw = read_xz_file('challenging-america-word-gap-prediction/train/in.tsv.xz')
 train_labels = read_file('challenging-america-word-gap-prediction/train/expected.tsv')
 train_sentences = compose_sentences(train_input_raw, train_labels)
 # In[21]:
 unk_token = '<unk>'
 # In[26]:
 class BaseDataset(torch.utils.data.Dataset):
    def __init__(
            self,
            sequence_length,
            sentences: list[str]
    ):
        self.sequence_length = sequence_length
        self.words = self.load(sentences)
        self.uniq_words = self.get_uniq_words()
        self.index_to_word = {index: word for index, word in enumerate(self.uniq_words)}
        self.word_to_index = {word: index for index, word in enumerate(self.uniq_words)}
        self.word_to_index[unk_token] = len(self.uniq_words)
        self.index_to_word[len(self.uniq_words)] = unk_token
        self.words_indexes = [self.word_to_index[w] for w in self.words]
    def get_uniq_words(self):
        word_counts = Counter(self.words)
        return sorted(word_counts, key=word_counts.get, reverse=True)
    def load(self, sentences: list[str]):
        raise NotImplementedError
    def __len__(self):
        return len(self.words_indexes) - self.sequence_length
    def __getitem__(self, index):
        return (
            torch.tensor(self.words_indexes[index:index + self.sequence_length]),
            torch.tensor(self.words_indexes[index + 1:index + self.sequence_length + 1]),
        )
 # In[27]:
 class ForwardDataset(BaseDataset):
    def load(self, sentences):
        words = [x.rstrip() for x in sentences if x.strip()]
        words = ' '.join(words).lower()
        words = words.split(' ')
        return words
 # In[28]:
 class BackwardsDataset(ForwardDataset):
    def load(self, sentences):
        words = super(BackwardsDataset, self).load(sentences)
        words.reverse()
        return words
 # In[29]:
 train_forwards_dataset = ForwardDataset(6, train_sentences)
 train_backwards_dataset = BackwardsDataset(6, train_sentences)
 # In[8]:
 from torch import nn, optim
 class LanguageModel(nn.Module):
    def __init__(self,
                 vocabulary_size=12800,
                 embedding_size=128,
                 hidden_size=256,
                 num_layers=4
                 ):
        super(LanguageModel, self).__init__()
        self.embedding_size = embedding_size
        self.embedding = nn.Embedding(vocabulary_size, embedding_size)
        self.gru = nn.GRU(
            input_size=self.embedding_size,
            hidden_size=hidden_size,
            num_layers=num_layers,
            dropout=0.2,
            batch_first=True
        )
        self.linear = nn.Linear(hidden_size, vocabulary_size)
    def forward(self, x, h=None):
        embeds = self.embedding(x)
        out, h = self.gru(embeds, h)
        out = self.linear(out)
        return out, h
 # In[9]:
 forward_model = LanguageModel(len(train_forwards_dataset)).to(device)
 # In[10]:
 from torch.utils.data import DataLoader
 from torch import save as save_model
 def train(model, dataset, max_epochs, batch_size, out_file):
    model.train()
    dataloader = DataLoader(dataset, batch_size=batch_size)
    criterion = nn.CrossEntropyLoss()
    optimizer = optim.Adam(model.parameters(), lr=0.001)
    for epoch in range(max_epochs):
        for batch, (x, y) in enumerate(dataloader):
            optimizer.zero_grad()
            x = x.to(device)
            y = y.to(device)
            y_pred, _ = model(x)
            loss = criterion(y_pred.transpose(1, 2), y)
            loss.backward()
            optimizer.step()
            print({'epoch': epoch, 'update in batch': batch, '/': len(dataloader), 'loss': loss.item()})
        save_model(model.state_dict(), out_file)
 # In[11]:
 train(forward_model, train_forwards_dataset, 10, 64, 'forward_model')
 # In[12]:
 backwards_model = LanguageModel(len(train_backwards_dataset)).to(device)
 train(backwards_model, train_backwards_dataset, 10, 64, 'backwards_model')
 # In[13]:
 dev_input_raw = read_xz_file('challenging-america-word-gap-prediction/dev-0/in.tsv.xz')
 dev_input_contexts = [get_contexts(input_text) for input_text in dev_input_raw]
 test_input_raw = read_xz_file('challenging-america-word-gap-prediction/test-A/in.tsv.xz')
 test_input_contexts = [get_contexts(input_text) for input_text in test_input_raw]
 # In[82]:
 from torch import topk
 from tqdm import tqdm
 import math
 def get_pairs_tokens_probs(model, sentence, dataset, top):
    preds = {}
    src = torch.tensor([[dataset.word_to_index.get(w, dataset.word_to_index[unk_token]) for w in sentence]]).to(device)
    output = model(src)
    top = topk(output[0][-1][-1], top)
    probs, tokens = top.values.tolist(), [dataset.index_to_word[idx] for idx in top.indices.tolist()]
    accumulated_probability = 0
    for prob, token in zip(probs, tokens):
        accumulated_probability += prob
        preds[token.strip()] = prob
    preds[''] = 1 - accumulated_probability
    return preds
 def trim_results(results: dict, top):
    """
    Przycinamy resultaty do `top` najbardziej prawdopodobnych wystąpień;
    prawdopodobieństwo wystąpienia pozostałych tokenów obliczamy na nowo
    """
    new = dict(sorted(results.items(), key=lambda item: item[1], reverse=True))
    del new['']
    new = {k[0]: k[1] for k in sorted(new.items(), key=lambda item: item[1], reverse=True)[:top-1]}
    new[''] = 1.0 - math.fsum(map(lambda x: float(x), new.values()))
    return new
 def merge_results(result: dict, other: dict, top):
    final = {}
    for left, right in zip(result.items(), other.items()):
        if left[0] in final:
            final[left[0]] = (final[left[0]] + left[1]) / 2
        else:
            final[left[0]] = left[1]
        if right[0] in final:
            final[right[0]] = (final[right[0]] + right[1]) / 2
        else:
            final[right[0]] = right[1]
    return trim_results(final, top)
 def predict_words(dataset: BaseDataset, fwd_model: LanguageModel, back_model: LanguageModel, sentences: list[dict],
                  top=50):
    preds = []
    for sentence in tqdm(sentences):
        left = sentence['left'].split(' ')
        right = sentence['right'].split(' ')
        left_results = get_pairs_tokens_probs(fwd_model, left, dataset, top)
        right_results = get_pairs_tokens_probs(back_model, right, dataset, top)
        merged_results = merge_results(left_results, right_results, top)
        results_as_string = ''
        for prob, token in merged_results.items():
            results_as_string += f'{token}:{prob} '
        preds.append(results_as_string)
    return preds
 # In[83]:
 dev_preds = predict_words(train_forwards_dataset, forward_model, backwards_model, dev_input_contexts)
 with open('challenging-america-word-gap-prediction/dev-0/out.tsv', 'w') as f:
    f.writelines(line + '\n' for line in dev_preds)
 # In[1]:
 test_preds = predict_words(test_input_contexts)
 with open('challenging-america-word-gap-prediction/test-A/out.tsv', 'w') as f:
    f.writelines(line + '\n' for line in test_preds)
--- a/test-A/out.tsv
+++ b/test-A/out.tsv