# cython: profile=True from __future__ import unicode_literals from libc.stdlib cimport calloc, free from ext.murmurhash cimport MurmurHash64A from ext.murmurhash cimport MurmurHash64B from spacy.lexeme cimport Lexeme from spacy.lexeme cimport BLANK_WORD from spacy.string_tools cimport substr from . import util from os import path cimport cython def get_normalized(unicode lex, size_t length): if lex.isalpha() and lex.islower(): return lex else: return get_word_shape(lex, length) def get_word_shape(lex, length): shape = "" last = "" shape_char = "" seq = 0 for c in lex: if c.isalpha(): if c.isupper(): shape_char = "X" else: shape_char = "x" elif c.isdigit(): shape_char = "d" else: shape_char = c if shape_char == last: seq += 1 else: seq = 0 last = shape_char if seq < 3: shape += shape_char assert shape return shape def set_orth_flags(lex, length): return 0 cdef class Language: def __cinit__(self, name): self.name = name self.bacov = {} self.vocab = new Vocab() self.ortho = new Vocab() self.distri = new Vocab() self.vocab[0].set_empty_key(0) self.distri[0].set_empty_key(0) self.ortho[0].set_empty_key(0) self.load_tokenization(util.read_tokenization(name)) def load_tokenization(self, token_rules=None): cdef Lexeme* word cdef StringHash hashed for chunk, lex, tokens in token_rules: hashed = self.hash_string(chunk, len(chunk)) word = self._add(hashed, lex, len(lex), len(lex)) for i, lex in enumerate(tokens): token_string = '%s:@:%d:@:%s' % (chunk, i, lex) length = len(token_string) hashed = self.hash_string(token_string, length) word.tail = self._add(hashed, lex, 0, len(lex)) word = word.tail def load_clusters(self): cdef Lexeme* w data_dir = path.join(path.dirname(__file__), '..', 'data', 'en') case_stats = util.load_case_stats(data_dir) brown_loc = path.join(data_dir, 'clusters') cdef size_t start cdef int end with util.utf8open(brown_loc) as browns_file: for i, line in enumerate(browns_file): cluster_str, token_string, freq_str = line.split() # Decode as a little-endian string, so that we can do & 15 to get # the first 4 bits. See redshift._parse_features.pyx cluster = int(cluster_str[::-1], 2) upper_pc, title_pc = case_stats.get(token_string.lower(), (0.0, 0.0)) hashed = self.hash_string(token_string, len(token_string)) word = self._add(hashed, token_string, len(token_string), len(token_string)) cdef StringHash hash_string(self, Py_UNICODE* s, size_t length) except 0: '''Hash unicode with MurmurHash64A''' return MurmurHash64A(s, length * sizeof(Py_UNICODE), 0) cdef unicode unhash(self, StringHash hash_value): '''Fetch a string from the reverse index, given its hash value.''' return self.bacov[hash_value] cdef Lexeme_addr lookup(self, int start, Py_UNICODE* string, size_t length) except 0: '''Fetch a Lexeme representing a word string. If the word has not been seen, construct one, splitting off any attached punctuation or clitics. A reference to BLANK_WORD is returned for the empty string. To specify the boundaries of the word if it has not been seen, use lookup_chunk. ''' if length == 0: return &BLANK_WORD cdef StringHash hashed = self.hash_string(string, length) cdef Lexeme* word_ptr = self.vocab[0][hashed] if word_ptr == NULL: start = self.find_split(string, length) if start == -1 else start word_ptr = self._add(hashed, string, start, length) return word_ptr cdef Lexeme* _add(self, StringHash hashed, unicode string, int split, size_t length): word = self.init_lexeme(string, hashed, split, length) self.vocab[0][hashed] = word self.bacov[hashed] = string return word cpdef Tokens tokenize(self, unicode string): cdef size_t length = len(string) cdef Py_UNICODE* characters = string cdef size_t i cdef Py_UNICODE c cdef Tokens tokens = Tokens(self) cdef Py_UNICODE* current = calloc(len(string), sizeof(Py_UNICODE)) cdef size_t word_len = 0 cdef Lexeme* token for i in range(length): c = characters[i] if _is_whitespace(c): if word_len != 0: token = self.lookup(-1, current, word_len) while token != NULL: tokens.append(token) token = token.tail for j in range(word_len+1): current[j] = 0 word_len = 0 else: current[word_len] = c word_len += 1 if word_len != 0: token = self.lookup(-1, current, word_len) while token != NULL: tokens.append(token) token = token.tail free(current) return tokens cdef int find_split(self, unicode word, size_t length): return -1 cdef Lexeme* init_lexeme(self, unicode string, StringHash hashed, int split, size_t length): cdef Lexeme* word = calloc(1, sizeof(Lexeme)) word.sic = hashed cdef unicode tail_string cdef unicode lex if split != 0 and split < length: lex = substr(string, 0, split, length) tail_string = substr(string, split, length, length) else: lex = string tail_string = '' word.lex = self.hash_string(lex, len(lex)) self.bacov[word.lex] = lex word.orth = self.ortho[0][word.lex] if word.orth == NULL: word.orth = self.init_orth(word.lex, lex) word.dist = self.distri[0][word.lex] # Now recurse, and deal with the tail if tail_string: word.tail = self.lookup(-1, tail_string, len(tail_string)) return word cdef Orthography* init_orth(self, StringHash hashed, unicode lex): cdef Orthography* orth = calloc(1, sizeof(Orthography)) orth.first = lex[0] cdef int length = len(lex) orth.flags = set_orth_flags(lex, length) cdef unicode last3 = substr(lex, length - 3, length, length) cdef unicode norm = get_normalized(lex, length) cdef unicode shape = get_word_shape(lex, length) orth.last3 = self.hash_string(last3, len(last3)) orth.shape = self.hash_string(shape, len(shape)) orth.norm = self.hash_string(norm, len(norm)) self.bacov[orth.last3] = last3 self.bacov[orth.shape] = shape self.bacov[orth.norm] = norm self.ortho[0][hashed] = orth return orth cdef inline bint _is_whitespace(Py_UNICODE c) nogil: if c == ' ': return True elif c == '\n': return True elif c == '\t': return True else: return False cpdef vector[size_t] expand_chunk(size_t addr) except *: cdef vector[size_t] tokens = vector[size_t]() word = addr while word != NULL: tokens.push_back(word) word = word.tail return tokens