# coding: utf8 from __future__ import unicode_literals import plac import math from tqdm import tqdm import numpy from ast import literal_eval from pathlib import Path from preshed.counter import PreshCounter import tarfile import gzip import zipfile from ._messages import Messages from ..vectors import Vectors from ..errors import Errors, Warnings, user_warning from ..util import prints, ensure_path, get_lang_class try: import ftfy except ImportError: ftfy = None @plac.annotations( lang=("model language", "positional", None, str), output_dir=("model output directory", "positional", None, Path), freqs_loc=("location of words frequencies file", "positional", None, Path), clusters_loc=("optional: location of brown clusters data", "option", "c", str), vectors_loc=("optional: location of vectors file in Word2Vec format " "(either as .txt or zipped as .zip or .tar.gz)", "option", "v", str), prune_vectors=("optional: number of vectors to prune to", "option", "V", int) ) def init_model(lang, output_dir, freqs_loc=None, clusters_loc=None, vectors_loc=None, prune_vectors=-1): """ Create a new model from raw data, like word frequencies, Brown clusters and word vectors. """ if freqs_loc is not None and not freqs_loc.exists(): prints(freqs_loc, title=Messages.M037, exits=1) clusters_loc = ensure_path(clusters_loc) vectors_loc = ensure_path(vectors_loc) probs, oov_prob = read_freqs(freqs_loc) if freqs_loc is not None else ({}, -20) vectors_data, vector_keys = read_vectors(vectors_loc) if vectors_loc else (None, None) clusters = read_clusters(clusters_loc) if clusters_loc else {} nlp = create_model(lang, probs, oov_prob, clusters, vectors_data, vector_keys, prune_vectors) if not output_dir.exists(): output_dir.mkdir() nlp.to_disk(output_dir) return nlp def open_file(loc): '''Handle .gz, .tar.gz or unzipped files''' loc = ensure_path(loc) print("Open loc") if tarfile.is_tarfile(str(loc)): return tarfile.open(str(loc), 'r:gz') elif loc.parts[-1].endswith('gz'): return (line.decode('utf8') for line in gzip.open(str(loc), 'r')) elif loc.parts[-1].endswith('zip'): zip_file = zipfile.ZipFile(str(loc)) names = zip_file.namelist() file_ = zip_file.open(names[0]) return (line.decode('utf8') for line in file_) else: return loc.open('r', encoding='utf8') def create_model(lang, probs, oov_prob, clusters, vectors_data, vector_keys, prune_vectors): print("Creating model...") lang_class = get_lang_class(lang) nlp = lang_class() for lexeme in nlp.vocab: lexeme.rank = 0 lex_added = 0 for i, (word, prob) in enumerate(tqdm(sorted(probs.items(), key=lambda item: item[1], reverse=True))): lexeme = nlp.vocab[word] lexeme.rank = i lexeme.prob = prob lexeme.is_oov = False # Decode as a little-endian string, so that we can do & 15 to get # the first 4 bits. See _parse_features.pyx if word in clusters: lexeme.cluster = int(clusters[word][::-1], 2) else: lexeme.cluster = 0 lex_added += 1 nlp.vocab.cfg.update({'oov_prob': oov_prob}) if vector_keys is not None: for word in vector_keys: if word not in nlp.vocab: lexeme = nlp.vocab[word] lexeme.is_oov = False lex_added += 1 if vectors_data: nlp.vocab.vectors = Vectors(data=vectors_data, keys=vector_keys) if prune_vectors >= 1: nlp.vocab.prune_vectors(prune_vectors) vec_added = len(nlp.vocab.vectors) prints(Messages.M039.format(entries=lex_added, vectors=vec_added), title=Messages.M038) return nlp def read_vectors(vectors_loc): print("Reading vectors from %s" % vectors_loc) f = open_file(vectors_loc) shape = tuple(int(size) for size in next(f).split()) vectors_data = numpy.zeros(shape=shape, dtype='f') vectors_keys = [] for i, line in enumerate(tqdm(f)): line = line.rstrip() pieces = line.rsplit(' ', vectors_data.shape[1]+1) word = pieces.pop(0) if len(pieces) != vectors_data.shape[1]: raise ValueError(Errors.E094.format(line_num=i, loc=vectors_loc)) vectors_data[i] = numpy.asarray(pieces, dtype='f') vectors_keys.append(word) return vectors_data, vectors_keys def read_freqs(freqs_loc, max_length=100, min_doc_freq=5, min_freq=50): print("Counting frequencies...") counts = PreshCounter() total = 0 with freqs_loc.open() as f: for i, line in enumerate(f): freq, doc_freq, key = line.rstrip().split('\t', 2) freq = int(freq) counts.inc(i + 1, freq) total += freq counts.smooth() log_total = math.log(total) probs = {} with freqs_loc.open() as f: for line in tqdm(f): freq, doc_freq, key = line.rstrip().split('\t', 2) doc_freq = int(doc_freq) freq = int(freq) if doc_freq >= min_doc_freq and freq >= min_freq and len(key) < max_length: word = literal_eval(key) smooth_count = counts.smoother(int(freq)) probs[word] = math.log(smooth_count) - log_total oov_prob = math.log(counts.smoother(0)) - log_total return probs, oov_prob def read_clusters(clusters_loc): print("Reading clusters...") clusters = {} if ftfy is None: user_warning(Warnings.W004) with clusters_loc.open() as f: for line in tqdm(f): try: cluster, word, freq = line.split() if ftfy is not None: word = ftfy.fix_text(word) except ValueError: continue # If the clusterer has only seen the word a few times, its # cluster is unreliable. if int(freq) >= 3: clusters[word] = cluster else: clusters[word] = '0' # Expand clusters with re-casing for word, cluster in list(clusters.items()): if word.lower() not in clusters: clusters[word.lower()] = cluster if word.title() not in clusters: clusters[word.title()] = cluster if word.upper() not in clusters: clusters[word.upper()] = cluster return clusters