from libc.string cimport memcpy from cpython.mem cimport PyMem_Malloc, PyMem_Free # Compiler crashes on memory view coercion without this. Should report bug. from cython.view cimport array as cvarray cimport numpy as np np.import_array() import numpy import six from ..lexeme cimport Lexeme from .. import parts_of_speech from ..attrs cimport LEMMA from ..attrs cimport ID, ORTH, NORM, LOWER, SHAPE, PREFIX, SUFFIX, LENGTH, CLUSTER from ..attrs cimport POS, LEMMA, TAG, DEP from ..parts_of_speech cimport CONJ, PUNCT from ..attrs cimport IS_ALPHA, IS_ASCII, IS_DIGIT, IS_LOWER, IS_PUNCT, IS_SPACE from ..attrs cimport FLAG14 as IS_BRACKET from ..attrs cimport FLAG15 as IS_QUOTE from ..attrs cimport FLAG16 as IS_LEFT_PUNCT from ..attrs cimport FLAG17 as IS_RIGHT_PUNCT from ..attrs cimport IS_TITLE, IS_UPPER, LIKE_URL, LIKE_NUM, LIKE_EMAIL, IS_STOP from ..attrs cimport IS_OOV from ..lexeme cimport Lexeme cdef class Token: """An individual token --- i.e. a word, a punctuation symbol, etc. Created via Doc.__getitem__ and Doc.__iter__. """ def __cinit__(self, Vocab vocab, Doc doc, int offset): self.vocab = vocab self.doc = doc self.c = &self.doc.c[offset] self.i = offset self.array_len = doc.length def __len__(self): return self.c.lex.length def __unicode__(self): return self.string def __bytes__(self): return self.string.encode('utf-8') def __str__(self): if six.PY3: return self.__unicode__() return self.__bytes__() def __repr__(self): return self.__str__() cpdef bint check_flag(self, attr_id_t flag_id) except -1: return Lexeme.c_check_flag(self.c.lex, flag_id) def nbor(self, int i=1): return self.doc[self.i+i] def similarity(self, other): if self.vector_norm == 0 or other.vector_norm == 0: return 0.0 return numpy.dot(self.vector, other.vector) / (self.vector_norm * other.vector_norm) property lex_id: def __get__(self): return self.c.lex.id property rank: def __get__(self): return self.c.lex.id property string: def __get__(self): return self.text_with_ws property text: def __get__(self): return self.orth_ property text_with_ws: def __get__(self): cdef unicode orth = self.vocab.strings[self.c.lex.orth] if self.c.spacy: return orth + u' ' else: return orth property prob: def __get__(self): return self.c.lex.prob property idx: def __get__(self): return self.c.idx property cluster: def __get__(self): return self.c.lex.cluster property orth: def __get__(self): return self.c.lex.orth property lower: def __get__(self): return self.c.lex.lower property norm: def __get__(self): return self.c.lex.norm property shape: def __get__(self): return self.c.lex.shape property prefix: def __get__(self): return self.c.lex.prefix property suffix: def __get__(self): return self.c.lex.suffix property lemma: def __get__(self): return self.c.lemma property pos: def __get__(self): return self.c.pos property tag: def __get__(self): return self.c.tag property dep: def __get__(self): return self.c.dep property has_vector: def __get__(self): cdef int i for i in range(self.vocab.vectors_length): if self.c.lex.vector[i] != 0: return True else: return False property vector: def __get__(self): cdef int length = self.vocab.vectors_length if length == 0: raise ValueError( "Word vectors set to length 0. This may be because the " "data is not installed. If you haven't already, run" "\npython -m spacy.en.download all\n" "to install the data." ) vector_view = self.c.lex.vector return numpy.asarray(vector_view) property repvec: def __get__(self): return self.vector property vector_norm: def __get__(self): return self.c.lex.l2_norm property n_lefts: def __get__(self): cdef int n = 0 cdef const TokenC* ptr = self.c - self.i while ptr != self.c: if ptr + ptr.head == self.c: n += 1 ptr += 1 return n property n_rights: def __get__(self): cdef int n = 0 cdef const TokenC* ptr = self.c + (self.array_len - self.i) while ptr != self.c: if ptr + ptr.head == self.c: n += 1 ptr -= 1 return n property lefts: def __get__(self): """The leftward immediate children of the word, in the syntactic dependency parse. """ cdef int nr_iter = 0 cdef const TokenC* ptr = self.c - (self.i - self.c.l_edge) while ptr < self.c: if ptr + ptr.head == self.c: yield self.doc[ptr - (self.c - self.i)] ptr += 1 nr_iter += 1 # This is ugly, but it's a way to guard out infinite loops if nr_iter >= 10000000: raise RuntimeError( "Possibly infinite loop encountered while looking for token.lefts") property rights: def __get__(self): """The rightward immediate children of the word, in the syntactic dependency parse.""" cdef const TokenC* ptr = self.c + (self.c.r_edge - self.i) tokens = [] cdef int nr_iter = 0 while ptr > self.c: if ptr + ptr.head == self.c: tokens.append(self.doc[ptr - (self.c - self.i)]) ptr -= 1 nr_iter += 1 if nr_iter >= 10000000: raise RuntimeError( "Possibly infinite loop encountered while looking for token.rights") tokens.reverse() for t in tokens: yield t property children: def __get__(self): yield from self.lefts yield from self.rights property subtree: def __get__(self): for word in self.lefts: yield from word.subtree yield self for word in self.rights: yield from word.subtree property left_edge: def __get__(self): return self.doc[self.c.l_edge] property right_edge: def __get__(self): return self.doc[self.c.r_edge] property head: def __get__(self): """The token predicted by the parser to be the head of the current token.""" return self.doc[self.i + self.c.head] property conjuncts: def __get__(self): """Get a list of conjoined words.""" cdef Token word if self.dep_ != 'conj': for word in self.rights: if word.dep_ == 'conj': yield word yield from word.conjuncts property ent_type: def __get__(self): return self.c.ent_type property ent_iob: def __get__(self): return self.c.ent_iob property ent_type_: def __get__(self): return self.vocab.strings[self.c.ent_type] property ent_iob_: def __get__(self): iob_strings = ('', 'I', 'O', 'B') return iob_strings[self.c.ent_iob] property whitespace_: def __get__(self): return ' ' if self.c.spacy else '' property orth_: def __get__(self): return self.vocab.strings[self.c.lex.orth] property lower_: def __get__(self): return self.vocab.strings[self.c.lex.lower] property norm_: def __get__(self): return self.vocab.strings[self.c.lex.norm] property shape_: def __get__(self): return self.vocab.strings[self.c.lex.shape] property prefix_: def __get__(self): return self.vocab.strings[self.c.lex.prefix] property suffix_: def __get__(self): return self.vocab.strings[self.c.lex.suffix] property lemma_: def __get__(self): return self.vocab.strings[self.c.lemma] property pos_: def __get__(self): return parts_of_speech.NAMES[self.c.pos] property tag_: def __get__(self): return self.vocab.strings[self.c.tag] property dep_: def __get__(self): return self.vocab.strings[self.c.dep] property is_oov: def __get__(self): return Lexeme.c_check_flag(self.c.lex, IS_OOV) property is_stop: def __get__(self): return Lexeme.c_check_flag(self.c.lex, IS_STOP) property is_alpha: def __get__(self): return Lexeme.c_check_flag(self.c.lex, IS_ALPHA) property is_ascii: def __get__(self): return Lexeme.c_check_flag(self.c.lex, IS_ASCII) property is_digit: def __get__(self): return Lexeme.c_check_flag(self.c.lex, IS_DIGIT) property is_lower: def __get__(self): return Lexeme.c_check_flag(self.c.lex, IS_LOWER) property is_title: def __get__(self): return Lexeme.c_check_flag(self.c.lex, IS_TITLE) property is_punct: def __get__(self): return Lexeme.c_check_flag(self.c.lex, IS_PUNCT) property is_space: def __get__(self): return Lexeme.c_check_flag(self.c.lex, IS_SPACE) property is_bracket: def __get__(self): return Lexeme.c_check_flag(self.c.lex, IS_BRACKET) property is_quote: def __get__(self): return Lexeme.c_check_flag(self.c.lex, IS_QUOTE) property is_left_punct: def __get__(self): return Lexeme.c_check_flag(self.c.lex, IS_LEFT_PUNCT) property is_right_punct: def __get__(self): return Lexeme.c_check_flag(self.c.lex, IS_RIGHT_PUNCT) property like_url: def __get__(self): return Lexeme.c_check_flag(self.c.lex, LIKE_URL) property like_num: def __get__(self): return Lexeme.c_check_flag(self.c.lex, LIKE_NUM) property like_email: def __get__(self): return Lexeme.c_check_flag(self.c.lex, LIKE_EMAIL)