from __future__ import unicode_literals from libc.stdio cimport fopen, fclose, fread, fwrite, FILE from libc.string cimport memset from libc.stdint cimport int32_t from libc.stdint cimport uint64_t from libc.math cimport sqrt import bz2 from os import path import io import math import ujson as json import tempfile from .lexeme cimport EMPTY_LEXEME from .lexeme cimport Lexeme from .strings cimport hash_string from .orth cimport word_shape from .typedefs cimport attr_t from .cfile cimport CFile from .lemmatizer import Lemmatizer from . import attrs from . import symbols from cymem.cymem cimport Address from .serialize.packer cimport Packer from .attrs cimport PROB, LANG from . import deprecated from . import util try: import copy_reg except ImportError: import copyreg as copy_reg DEF MAX_VEC_SIZE = 100000 cdef float[MAX_VEC_SIZE] EMPTY_VEC memset(EMPTY_VEC, 0, sizeof(EMPTY_VEC)) memset(&EMPTY_LEXEME, 0, sizeof(LexemeC)) EMPTY_LEXEME.vector = EMPTY_VEC cdef class Vocab: '''A map container for a language's LexemeC structs. ''' @classmethod def load(cls, path, lex_attr_getters=None, lemmatizer=True, tag_map=True, serializer_freqs=True, oov_prob=True, **deprecated_kwargs): util.check_renamed_kwargs({'get_lex_attr': 'lex_attr_getters'}, deprecated_kwargs) if 'vectors' in deprecated_kwargs: raise AttributeError( "vectors argument to Vocab.load() deprecated. " "Install vectors after loading.") if tag_map is True and (path / 'vocab' / 'tag_map.json').exists(): with (path / 'vocab' / 'tag_map.json').open('r', encoding='utf8') as file_: tag_map = json.load(file_) if lex_attr_getters is not None \ and oov_prob is True \ and (path / 'vocab' / 'oov_prob').exists(): with (path / 'vocab' / 'oov_prob').open('r', encoding='utf8') as file_: oov_prob = float(file_.read()) lex_attr_getters[PROB] = lambda text: oov_prob if lemmatizer is True: lemmatizer = Lemmatizer.load(path) if serializer_freqs is True and (path / 'vocab' / 'serializer.json').exists(): with (path / 'vocab' / 'serializer.json').open('r', encoding='utf8') as file_: serializer_freqs = json.load(file_) cdef Vocab self = cls(lex_attr_getters=lex_attr_getters, tag_map=tag_map, lemmatizer=lemmatizer, serializer_freqs=serializer_freqs) with (path / 'vocab' / 'strings.json').open('r', encoding='utf8') as file_: self.strings.load(file_) self.load_lexemes(path / 'vocab' / 'lexemes.bin') return self def __init__(self, lex_attr_getters=None, tag_map=None, lemmatizer=None, serializer_freqs=None, **deprecated_kwargs): util.check_renamed_kwargs({'get_lex_attr': 'lex_attr_getters'}, deprecated_kwargs) lex_attr_getters = lex_attr_getters if lex_attr_getters is not None else {} tag_map = tag_map if tag_map is not None else {} if lemmatizer in (None, True, False): lemmatizer = Lemmatizer({}, {}, {}) serializer_freqs = serializer_freqs if serializer_freqs is not None else {} self.mem = Pool() self._by_hash = PreshMap() self._by_orth = PreshMap() self.strings = StringStore() # Load strings in a special order, so that we have an onset number for # the vocabulary. This way, when words are added in order, the orth ID # is the frequency rank of the word, plus a certain offset. The structural # strings are loaded first, because the vocab is open-class, and these # symbols are closed class. # TODO: Actually this has turned out to be a pain in the ass... # It means the data is invalidated when we add a symbol :( # Need to rethink this. for name in symbols.NAMES + list(sorted(tag_map.keys())): if name: _ = self.strings[name] self.lex_attr_getters = lex_attr_getters self.morphology = Morphology(self.strings, tag_map, lemmatizer) self.serializer_freqs = serializer_freqs self.length = 1 self._serializer = None property serializer: def __get__(self): if self._serializer is None: freqs = [] self._serializer = Packer(self, self.serializer_freqs) return self._serializer property lang: def __get__(self): langfunc = None if self.lex_attr_getters: langfunc = self.lex_attr_getters.get(LANG, None) return langfunc('_') if langfunc else '' def __len__(self): """The current number of lexemes stored.""" return self.length def resize_vectors(self, int new_size): ''' Set vectors_length to a new size, and allocate more memory for the Lexeme vectors if necessary. The memory will be zeroed. ''' cdef hash_t key cdef size_t addr if new_size > self.vectors_length: for key, addr in self._by_hash.items(): lex = addr lex.vector = self.mem.realloc(lex.vector, new_size * sizeof(lex.vector[0])) self.vectors_length = new_size def add_flag(self, flag_getter, int flag_id=-1): '''Set a new boolean flag to words in the vocabulary. The flag_setter function will be called over the words currently in the vocab, and then applied to new words as they occur. You'll then be able to access the flag value on each token, using token.check_flag(flag_id). See also: Lexeme.set_flag, Lexeme.check_flag, Token.set_flag, Token.check_flag. Arguments: flag_getter: A function f(unicode) -> bool, to get the flag value. flag_id (int): An integer between 1 and 63 (inclusive), specifying the bit at which the flag will be stored. If -1, the lowest available bit will be chosen. Returns: flag_id (int): The integer ID by which the flag value can be checked. ''' if flag_id == -1: for bit in range(1, 64): if bit not in self.lex_attr_getters: flag_id = bit break else: raise ValueError( "Cannot find empty bit for new lexical flag. All bits between " "0 and 63 are occupied. You can replace one by specifying the " "flag_id explicitly, e.g. nlp.vocab.add_flag(your_func, flag_id=IS_ALPHA") elif flag_id >= 64 or flag_id < 1: raise ValueError( "Invalid value for flag_id: %d. Flag IDs must be between " "1 and 63 (inclusive)" % flag_id) for lex in self: lex.set_flag(flag_id, flag_getter(lex.orth_)) self.lex_attr_getters[flag_id] = flag_getter return flag_id cdef const LexemeC* get(self, Pool mem, unicode string) except NULL: '''Get a pointer to a LexemeC from the lexicon, creating a new Lexeme if necessary, using memory acquired from the given pool. If the pool is the lexicon's own memory, the lexeme is saved in the lexicon.''' if string == u'': return &EMPTY_LEXEME cdef LexemeC* lex cdef hash_t key = hash_string(string) lex = self._by_hash.get(key) cdef size_t addr if lex != NULL: if lex.orth != self.strings[string]: raise LookupError.mismatched_strings( lex.orth, self.strings[string], self.strings[lex.orth], string) return lex else: return self._new_lexeme(mem, string) cdef const LexemeC* get_by_orth(self, Pool mem, attr_t orth) except NULL: '''Get a pointer to a LexemeC from the lexicon, creating a new Lexeme if necessary, using memory acquired from the given pool. If the pool is the lexicon's own memory, the lexeme is saved in the lexicon.''' if orth == 0: return &EMPTY_LEXEME cdef LexemeC* lex lex = self._by_orth.get(orth) if lex != NULL: return lex else: return self._new_lexeme(mem, self.strings[orth]) cdef const LexemeC* _new_lexeme(self, Pool mem, unicode string) except NULL: cdef hash_t key cdef bint is_oov = mem is not self.mem if len(string) < 3: mem = self.mem lex = mem.alloc(sizeof(LexemeC), 1) lex.orth = self.strings[string] lex.length = len(string) lex.id = self.length lex.vector = mem.alloc(self.vectors_length, sizeof(float)) if self.lex_attr_getters is not None: for attr, func in self.lex_attr_getters.items(): value = func(string) if isinstance(value, unicode): value = self.strings[value] if attr == PROB: lex.prob = value elif value is not None: Lexeme.set_struct_attr(lex, attr, value) if is_oov: lex.id = 0 else: key = hash_string(string) self._add_lex_to_vocab(key, lex) assert lex != NULL, string return lex cdef int _add_lex_to_vocab(self, hash_t key, const LexemeC* lex) except -1: self._by_hash.set(key, lex) self._by_orth.set(lex.orth, lex) self.length += 1 def __contains__(self, unicode string): key = hash_string(string) lex = self._by_hash.get(key) return True if lex is not NULL else False def __iter__(self): cdef attr_t orth cdef size_t addr for orth, addr in self._by_orth.items(): yield Lexeme(self, orth) def __getitem__(self, id_or_string): '''Retrieve a lexeme, given an int ID or a unicode string. If a previously unseen unicode string is given, a new lexeme is created and stored. Args: id_or_string (int or unicode): The integer ID of a word, or its unicode string. If an int >= Lexicon.size, IndexError is raised. If id_or_string is neither an int nor a unicode string, ValueError is raised. Returns: lexeme (Lexeme): An instance of the Lexeme Python class, with data copied on instantiation. ''' cdef attr_t orth if type(id_or_string) == unicode: orth = self.strings[id_or_string] else: orth = id_or_string return Lexeme(self, orth) cdef const TokenC* make_fused_token(self, substrings) except NULL: cdef int i tokens = self.mem.alloc(len(substrings) + 1, sizeof(TokenC)) for i, props in enumerate(substrings): token = &tokens[i] # Set the special tokens up to have morphology and lemmas if # specified, otherwise use the part-of-speech tag (if specified) token.lex = self.get(self.mem, props['F']) if 'pos' in props: self.morphology.assign_tag(token, props['pos']) if 'L' in props: tokens[i].lemma = self.strings[props['L']] for feature, value in props.get('morph', {}).items(): self.morphology.assign_feature(&token.morph, feature, value) return tokens def dump(self, loc): if hasattr(loc, 'as_posix'): loc = loc.as_posix() cdef bytes bytes_loc = loc.encode('utf8') if type(loc) == unicode else loc cdef CFile fp = CFile(bytes_loc, 'wb') cdef size_t st cdef size_t addr cdef hash_t key for key, addr in self._by_hash.items(): lexeme = addr fp.write_from(&lexeme.orth, sizeof(lexeme.orth), 1) fp.write_from(&lexeme.flags, sizeof(lexeme.flags), 1) fp.write_from(&lexeme.id, sizeof(lexeme.id), 1) fp.write_from(&lexeme.length, sizeof(lexeme.length), 1) fp.write_from(&lexeme.orth, sizeof(lexeme.orth), 1) fp.write_from(&lexeme.lower, sizeof(lexeme.lower), 1) fp.write_from(&lexeme.norm, sizeof(lexeme.norm), 1) fp.write_from(&lexeme.shape, sizeof(lexeme.shape), 1) fp.write_from(&lexeme.prefix, sizeof(lexeme.prefix), 1) fp.write_from(&lexeme.suffix, sizeof(lexeme.suffix), 1) fp.write_from(&lexeme.cluster, sizeof(lexeme.cluster), 1) fp.write_from(&lexeme.prob, sizeof(lexeme.prob), 1) fp.write_from(&lexeme.sentiment, sizeof(lexeme.sentiment), 1) fp.write_from(&lexeme.l2_norm, sizeof(lexeme.l2_norm), 1) fp.write_from(&lexeme.lang, sizeof(lexeme.lang), 1) fp.close() def load_lexemes(self, loc): fp = CFile(loc, 'rb', on_open_error=lambda: IOError('LexemeCs file not found at %s' % loc)) cdef LexemeC* lexeme cdef hash_t key cdef unicode py_str cdef attr_t orth assert sizeof(orth) == sizeof(lexeme.orth) i = 0 while True: try: fp.read_into(&orth, 1, sizeof(orth)) except IOError: break lexeme = self.mem.alloc(sizeof(LexemeC), 1) # Copy data from the file into the lexeme fp.read_into(&lexeme.flags, 1, sizeof(lexeme.flags)) fp.read_into(&lexeme.id, 1, sizeof(lexeme.id)) fp.read_into(&lexeme.length, 1, sizeof(lexeme.length)) fp.read_into(&lexeme.orth, 1, sizeof(lexeme.orth)) fp.read_into(&lexeme.lower, 1, sizeof(lexeme.lower)) fp.read_into(&lexeme.norm, 1, sizeof(lexeme.norm)) fp.read_into(&lexeme.shape, 1, sizeof(lexeme.shape)) fp.read_into(&lexeme.prefix, 1, sizeof(lexeme.prefix)) fp.read_into(&lexeme.suffix, 1, sizeof(lexeme.suffix)) fp.read_into(&lexeme.cluster, 1, sizeof(lexeme.cluster)) fp.read_into(&lexeme.prob, 1, sizeof(lexeme.prob)) fp.read_into(&lexeme.sentiment, 1, sizeof(lexeme.sentiment)) fp.read_into(&lexeme.l2_norm, 1, sizeof(lexeme.l2_norm)) fp.read_into(&lexeme.lang, 1, sizeof(lexeme.lang)) lexeme.vector = EMPTY_VEC py_str = self.strings[lexeme.orth] key = hash_string(py_str) self._by_hash.set(key, lexeme) self._by_orth.set(lexeme.orth, lexeme) self.length += 1 i += 1 fp.close() def dump_vectors(self, out_loc): cdef int32_t vec_len = self.vectors_length cdef int32_t word_len cdef bytes word_str cdef char* chars cdef Lexeme lexeme cdef CFile out_file = CFile(out_loc, 'wb') for lexeme in self: word_str = lexeme.orth_.encode('utf8') vec = lexeme.c.vector word_len = len(word_str) out_file.write_from(&word_len, 1, sizeof(word_len)) out_file.write_from(&vec_len, 1, sizeof(vec_len)) chars = word_str out_file.write_from(chars, word_len, sizeof(char)) out_file.write_from(vec, vec_len, sizeof(float)) out_file.close() def load_vectors(self, file_): cdef LexemeC* lexeme cdef attr_t orth cdef int32_t vec_len = -1 cdef double norm = 0.0 for line_num, line in enumerate(file_): pieces = line.split() word_str = pieces.pop(0) if vec_len == -1: vec_len = len(pieces) elif vec_len != len(pieces): raise VectorReadError.mismatched_sizes(file_, line_num, vec_len, len(pieces)) orth = self.strings[word_str] lexeme = self.get_by_orth(self.mem, orth) lexeme.vector = self.mem.alloc(vec_len, sizeof(float)) for i, val_str in enumerate(pieces): lexeme.vector[i] = float(val_str) norm = 0.0 for i in range(vec_len): norm += lexeme.vector[i] * lexeme.vector[i] lexeme.l2_norm = sqrt(norm) self.vectors_length = vec_len return vec_len def load_vectors_from_bin_loc(self, loc): cdef CFile file_ = CFile(loc, b'rb') cdef int32_t word_len cdef int32_t vec_len = 0 cdef int32_t prev_vec_len = 0 cdef float* vec cdef Address mem cdef attr_t string_id cdef bytes py_word cdef vector[float*] vectors cdef int line_num = 0 cdef Pool tmp_mem = Pool() while True: try: file_.read_into(&word_len, sizeof(word_len), 1) except IOError: break file_.read_into(&vec_len, sizeof(vec_len), 1) if prev_vec_len != 0 and vec_len != prev_vec_len: raise VectorReadError.mismatched_sizes(loc, line_num, vec_len, prev_vec_len) if 0 >= vec_len >= MAX_VEC_SIZE: raise VectorReadError.bad_size(loc, vec_len) chars = file_.alloc_read(tmp_mem, word_len, sizeof(char)) vec = file_.alloc_read(self.mem, vec_len, sizeof(float)) string_id = self.strings[chars[:word_len]] while string_id >= vectors.size(): vectors.push_back(EMPTY_VEC) assert vec != NULL vectors[string_id] = vec line_num += 1 cdef LexemeC* lex cdef size_t lex_addr cdef double norm = 0.0 cdef int i for orth, lex_addr in self._by_orth.items(): lex = lex_addr if lex.lower < vectors.size(): lex.vector = vectors[lex.lower] for i in range(vec_len): norm += lex.vector[i] * lex.vector[i] lex.l2_norm = sqrt(norm) else: lex.vector = EMPTY_VEC self.vectors_length = vec_len return vec_len def write_binary_vectors(in_loc, out_loc): cdef CFile out_file = CFile(out_loc, 'wb') cdef Address mem cdef int32_t word_len cdef int32_t vec_len cdef char* chars with bz2.BZ2File(in_loc, 'r') as file_: for line in file_: pieces = line.split() word = pieces.pop(0) mem = Address(len(pieces), sizeof(float)) vec = mem.ptr for i, val_str in enumerate(pieces): vec[i] = float(val_str) word_len = len(word) vec_len = len(pieces) out_file.write_from(&word_len, 1, sizeof(word_len)) out_file.write_from(&vec_len, 1, sizeof(vec_len)) chars = word out_file.write_from(chars, len(word), sizeof(char)) out_file.write_from(vec, vec_len, sizeof(float)) class LookupError(Exception): @classmethod def mismatched_strings(cls, id_, id_string, original_string): return cls( "Error fetching a Lexeme from the Vocab. When looking up a string, " "the lexeme returned had an orth ID that did not match the query string. " "This means that the cached lexeme structs are mismatched to the " "string encoding table. The mismatched:\n" "Query string: {query}\n" "Orth cached: {orth_str}\n" "ID of orth: {orth_id}".format( query=repr(original_string), orth_str=repr(id_string), orth_id=id_) ) class VectorReadError(Exception): @classmethod def mismatched_sizes(cls, loc, line_num, prev_size, curr_size): return cls( "Error reading word vectors from %s on line %d.\n" "All vectors must be the same size.\n" "Prev size: %d\n" "Curr size: %d" % (loc, line_num, prev_size, curr_size)) @classmethod def bad_size(cls, loc, size): return cls( "Error reading word vectors from %s.\n" "Vector size: %d\n" "Max size: %d\n" "Min size: 1\n" % (loc, size, MAX_VEC_SIZE))