Ejemplo n.º 1
0
Instance *SequenceReader::GetNext() {
  // Fill all fields for the entire sentence.
  vector<vector<string> > sentence_fields;
  string line;
  if (is_.is_open()) {
    while (!is_.eof()) {
      getline(is_, line);
      if (line.length() <= 0) break;
      vector<string> fields;
      StringSplit(line, "\t", &fields);
      sentence_fields.push_back(fields);
    }
  }

  // Sentence length.
  int length = sentence_fields.size();

  // Convert to array of words and tags.
  vector<string> forms(length);
  vector<string> tags(length);

  for(int i = 0; i < length; ++i) {
    const vector<string> &info = sentence_fields[i];
    forms[i] = info[0];
    tags[i] = info[1];
  }

  SequenceInstance *instance = NULL;
  if (length > 0) {
    instance = new SequenceInstance;
    instance->Initialize(forms, tags);
  }

  return static_cast<Instance*>(instance);
}
Ejemplo n.º 2
0
void TokenDictionary::InitializeFromSequenceReader(SequenceReader *reader) {
  LOG(INFO) << "Creating token dictionary...";

  int form_cutoff = FLAGS_form_cutoff;
  int form_lower_cutoff = FLAGS_form_cutoff;
  int shape_cutoff = 0;
  int prefix_length = FLAGS_prefix_length;
  int suffix_length = FLAGS_suffix_length;
  bool form_case_sensitive = FLAGS_form_case_sensitive;

  std::vector<int> form_freqs;
  std::vector<int> form_lower_freqs;
  std::vector<int> shape_freqs;
  Alphabet form_alphabet;
  Alphabet form_lower_alphabet;
  Alphabet shape_alphabet;

  std::string special_symbols[NUM_SPECIAL_TOKENS];
  special_symbols[TOKEN_UNKNOWN] = kTokenUnknown;
  special_symbols[TOKEN_START] = kTokenStart;
  special_symbols[TOKEN_STOP] = kTokenStop;

  for (int i = 0; i < NUM_SPECIAL_TOKENS; ++i) {
    prefix_alphabet_.Insert(special_symbols[i]);
    suffix_alphabet_.Insert(special_symbols[i]);
    form_alphabet.Insert(special_symbols[i]);
    form_lower_alphabet.Insert(special_symbols[i]);
    shape_alphabet.Insert(special_symbols[i]);

    // Counts of special symbols are set to -1:
    form_freqs.push_back(-1);
    form_lower_freqs.push_back(-1);
    shape_freqs.push_back(-1);
  }

  // Go through the corpus and build the dictionaries,
  // counting the frequencies.
  reader->Open(pipe_->GetOptions()->GetTrainingFilePath());
  SequenceInstance *instance =
    static_cast<SequenceInstance*>(reader->GetNext());
  while (instance != NULL) {
    int instance_length = instance->size();
    for (int i = 0; i < instance_length; ++i) {
      int id;

      // Add form to alphabet.
      std::string form = instance->GetForm(i);
      std::string form_lower(form);
      transform(form_lower.begin(), form_lower.end(), form_lower.begin(),
                ::tolower);
      if (!form_case_sensitive) form = form_lower;
      id = form_alphabet.Insert(form);
      if (id >= form_freqs.size()) {
        CHECK_EQ(id, form_freqs.size());
        form_freqs.push_back(0);
      }
      ++form_freqs[id];

      // Add lower-case form to the alphabet.
      id = form_lower_alphabet.Insert(form_lower);
      if (id >= form_lower_freqs.size()) {
        CHECK_EQ(id, form_lower_freqs.size());
        form_lower_freqs.push_back(0);
      }
      ++form_lower_freqs[id];

      // Add prefix/suffix to alphabet.
      std::string prefix = form.substr(0, prefix_length);
      id = prefix_alphabet_.Insert(prefix);
      int start = form.length() - suffix_length;
      if (start < 0) start = 0;
      std::string suffix = form.substr(start, suffix_length);
      id = suffix_alphabet_.Insert(suffix);

      // Add shape to alphabet.
      std::string shape;
      GetWordShape(instance->GetForm(i), &shape);
      id = shape_alphabet.Insert(shape);
      if (id >= shape_freqs.size()) {
        CHECK_EQ(id, shape_freqs.size());
        shape_freqs.push_back(0);
      }
      ++shape_freqs[id];
    }
    delete instance;
    instance = static_cast<SequenceInstance*>(reader->GetNext());
  }
  reader->Close();

  // Now adjust the cutoffs if necessary.
  while (true) {
    form_alphabet_.clear();
    for (int i = 0; i < NUM_SPECIAL_TOKENS; ++i) {
      form_alphabet_.Insert(special_symbols[i]);
    }
    for (Alphabet::iterator iter = form_alphabet.begin();
         iter != form_alphabet.end();
         ++iter) {
      if (form_freqs[iter->second] > form_cutoff) {
        form_alphabet_.Insert(iter->first);
      }
    }
    if (form_alphabet_.size() < kMaxFormAlphabetSize) break;
    ++form_cutoff;
    LOG(INFO) << "Incrementing form cutoff to " << form_cutoff << "...";
  }

  while (true) {
    form_lower_alphabet_.clear();
    for (int i = 0; i < NUM_SPECIAL_TOKENS; ++i) {
      form_lower_alphabet_.Insert(special_symbols[i]);
    }
    for (Alphabet::iterator iter = form_lower_alphabet.begin();
         iter != form_lower_alphabet.end();
         ++iter) {
      if (form_lower_freqs[iter->second] > form_lower_cutoff) {
        form_lower_alphabet_.Insert(iter->first);
      }
    }
    if (form_lower_alphabet_.size() < kMaxFormAlphabetSize) break;
    ++form_lower_cutoff;
    LOG(INFO) << "Incrementing lower-case form cutoff to "
              << form_lower_cutoff << "...";
  }

  while (true) {
    shape_alphabet_.clear();
    for (int i = 0; i < NUM_SPECIAL_TOKENS; ++i) {
      shape_alphabet_.Insert(special_symbols[i]);
    }
    for (Alphabet::iterator iter = shape_alphabet.begin();
         iter != shape_alphabet.end();
         ++iter) {
      if (shape_freqs[iter->second] > shape_cutoff) {
        shape_alphabet_.Insert(iter->first);
      }
    }
    if (shape_alphabet_.size() < kMaxShapeAlphabetSize) break;
    ++shape_cutoff;
    LOG(INFO) << "Incrementing shape cutoff to " << shape_cutoff << "...";
  }

  form_alphabet_.StopGrowth();
  form_lower_alphabet_.StopGrowth();
  shape_alphabet_.StopGrowth();
  lemma_alphabet_.StopGrowth();
  prefix_alphabet_.StopGrowth();
  suffix_alphabet_.StopGrowth();
  feats_alphabet_.StopGrowth();
  pos_alphabet_.StopGrowth();
  cpos_alphabet_.StopGrowth();

  LOG(INFO) << "Number of forms: " << form_alphabet_.size() << endl
            << "Number of prefixes: "
            << prefix_alphabet_.size() << endl
            << "Number of suffixes: "
            << suffix_alphabet_.size() << endl
            << "Number of word shapes: "
            << shape_alphabet_.size();

  CHECK_LT(form_alphabet_.size(), 0xffff);
  CHECK_LT(form_lower_alphabet_.size(), 0xffff);
  CHECK_LT(shape_alphabet_.size(), 0xffff);
  CHECK_LT(lemma_alphabet_.size(), 0xffff);
  CHECK_LT(prefix_alphabet_.size(), 0xffff);
  CHECK_LT(suffix_alphabet_.size(), 0xffff);
  CHECK_LT(feats_alphabet_.size(), 0xffff);
  CHECK_LT(pos_alphabet_.size(), 0xff);
  CHECK_LT(cpos_alphabet_.size(), 0xff);
}
Ejemplo n.º 3
0
void TaggerDictionary::CreateTagDictionary(SequenceReader *reader) {
  SequenceDictionary::CreateTagDictionary(reader);

  LOG(INFO) << "Creating word-tag dictionary...";
  bool form_case_sensitive = FLAGS_form_case_sensitive;

  // Go through the corpus and build the existing tags for each word.
  word_tags_.clear();
  word_tags_.resize(token_dictionary_->GetNumForms());

  reader->Open(pipe_->GetOptions()->GetTrainingFilePath());
  SequenceInstance *instance =
    static_cast<SequenceInstance*>(reader->GetNext());
  while (instance != NULL) {
    int instance_length = instance->size();
    for (int i = 0; i < instance_length; ++i) {
      int id;
      string form = instance->GetForm(i);
      if (!form_case_sensitive) {
        transform(form.begin(), form.end(), form.begin(), ::tolower);
      }
      int word_id = token_dictionary_->GetFormId(form);
      //CHECK_GE(word_id, 0);

      id = tag_alphabet_.Lookup(instance->GetTag(i));
      CHECK_GE(id, 0);

      // Insert new tag in the set of word tags, if it is not there
      // already. NOTE: this is inefficient, maybe we should be using a
      // different data structure.
      if (word_id >= 0) {
        vector<int> &tags = word_tags_[word_id];
        int j;
        for (j = 0; j < tags.size(); ++j) {
          if (tags[j] == id) break;
        }
        if (j == tags.size()) tags.push_back(id);
      }
    }
    delete instance;
    instance = static_cast<SequenceInstance*>(reader->GetNext());
  }
  reader->Close();

  // If there is a list of possible tags for the unknown words, load it.
  TaggerOptions *options =
    static_cast<TaggerOptions*>(pipe_->GetOptions());
  if (options->GetUnknownWordTagsFilePath().size() == 0) {
    for (int i = 0; i < tag_alphabet_.size(); ++i) {
      unknown_word_tags_.push_back(i);
    }
  } else {
    LOG(INFO) << "Loading file with unknown word tags...";
    std::ifstream is;
    is.open(options->GetUnknownWordTagsFilePath().c_str(), ifstream::in);
    CHECK(is.good()) << "Could not open "
      << options->GetUnknownWordTagsFilePath() << ".";
    vector<vector<string> > sentence_fields;
    string line;
    if (is.is_open()) {
      while (!is.eof()) {
        getline(is, line);
        if (line.size() == 0) break;
        int tagid = tag_alphabet_.Lookup(line);
        CHECK(tagid >= 0) << "Tag " << line << " does not exist.";
        unknown_word_tags_.push_back(tagid);
        LOG(INFO) << "Unknown word tag: " << line;
      }
    }
  }
  LOG(INFO) << "Number of unknown word tags: " << unknown_word_tags_.size();
}