# Natural Language Toolkit: Tokenizer Utilities # # Copyright (C) 2001-2023 NLTK Project # Author: Steven Bird # URL: # For license information, see LICENSE.TXT from re import finditer from xml.sax.saxutils import escape, unescape def string_span_tokenize(s, sep): r""" Return the offsets of the tokens in *s*, as a sequence of ``(start, end)`` tuples, by splitting the string at each occurrence of *sep*. >>> from nltk.tokenize.util import string_span_tokenize >>> s = '''Good muffins cost $3.88\nin New York. Please buy me ... two of them.\n\nThanks.''' >>> list(string_span_tokenize(s, " ")) # doctest: +NORMALIZE_WHITESPACE [(0, 4), (5, 12), (13, 17), (18, 26), (27, 30), (31, 36), (37, 37), (38, 44), (45, 48), (49, 55), (56, 58), (59, 73)] :param s: the string to be tokenized :type s: str :param sep: the token separator :type sep: str :rtype: iter(tuple(int, int)) """ if len(sep) == 0: raise ValueError("Token delimiter must not be empty") left = 0 while True: try: right = s.index(sep, left) if right != 0: yield left, right except ValueError: if left != len(s): yield left, len(s) break left = right + len(sep) def regexp_span_tokenize(s, regexp): r""" Return the offsets of the tokens in *s*, as a sequence of ``(start, end)`` tuples, by splitting the string at each successive match of *regexp*. >>> from nltk.tokenize.util import regexp_span_tokenize >>> s = '''Good muffins cost $3.88\nin New York. Please buy me ... two of them.\n\nThanks.''' >>> list(regexp_span_tokenize(s, r'\s')) # doctest: +NORMALIZE_WHITESPACE [(0, 4), (5, 12), (13, 17), (18, 23), (24, 26), (27, 30), (31, 36), (38, 44), (45, 48), (49, 51), (52, 55), (56, 58), (59, 64), (66, 73)] :param s: the string to be tokenized :type s: str :param regexp: regular expression that matches token separators (must not be empty) :type regexp: str :rtype: iter(tuple(int, int)) """ left = 0 for m in finditer(regexp, s): right, next = m.span() if right != left: yield left, right left = next yield left, len(s) def spans_to_relative(spans): r""" Return a sequence of relative spans, given a sequence of spans. >>> from nltk.tokenize import WhitespaceTokenizer >>> from nltk.tokenize.util import spans_to_relative >>> s = '''Good muffins cost $3.88\nin New York. Please buy me ... two of them.\n\nThanks.''' >>> list(spans_to_relative(WhitespaceTokenizer().span_tokenize(s))) # doctest: +NORMALIZE_WHITESPACE [(0, 4), (1, 7), (1, 4), (1, 5), (1, 2), (1, 3), (1, 5), (2, 6), (1, 3), (1, 2), (1, 3), (1, 2), (1, 5), (2, 7)] :param spans: a sequence of (start, end) offsets of the tokens :type spans: iter(tuple(int, int)) :rtype: iter(tuple(int, int)) """ prev = 0 for left, right in spans: yield left - prev, right - left prev = right class CJKChars: """ An object that enumerates the code points of the CJK characters as listed on https://en.wikipedia.org/wiki/Basic_Multilingual_Plane#Basic_Multilingual_Plane This is a Python port of the CJK code point enumerations of Moses tokenizer: https://github.com/moses-smt/mosesdecoder/blob/master/scripts/tokenizer/detokenizer.perl#L309 """ # Hangul Jamo (1100–11FF) Hangul_Jamo = (4352, 4607) # (ord(u"\u1100"), ord(u"\u11ff")) # CJK Radicals Supplement (2E80–2EFF) # Kangxi Radicals (2F00–2FDF) # Ideographic Description Characters (2FF0–2FFF) # CJK Symbols and Punctuation (3000–303F) # Hiragana (3040–309F) # Katakana (30A0–30FF) # Bopomofo (3100–312F) # Hangul Compatibility Jamo (3130–318F) # Kanbun (3190–319F) # Bopomofo Extended (31A0–31BF) # CJK Strokes (31C0–31EF) # Katakana Phonetic Extensions (31F0–31FF) # Enclosed CJK Letters and Months (3200–32FF) # CJK Compatibility (3300–33FF) # CJK Unified Ideographs Extension A (3400–4DBF) # Yijing Hexagram Symbols (4DC0–4DFF) # CJK Unified Ideographs (4E00–9FFF) # Yi Syllables (A000–A48F) # Yi Radicals (A490–A4CF) CJK_Radicals = (11904, 42191) # (ord(u"\u2e80"), ord(u"\ua4cf")) # Phags-pa (A840–A87F) Phags_Pa = (43072, 43135) # (ord(u"\ua840"), ord(u"\ua87f")) # Hangul Syllables (AC00–D7AF) Hangul_Syllables = (44032, 55215) # (ord(u"\uAC00"), ord(u"\uD7AF")) # CJK Compatibility Ideographs (F900–FAFF) CJK_Compatibility_Ideographs = (63744, 64255) # (ord(u"\uF900"), ord(u"\uFAFF")) # CJK Compatibility Forms (FE30–FE4F) CJK_Compatibility_Forms = (65072, 65103) # (ord(u"\uFE30"), ord(u"\uFE4F")) # Range U+FF65–FFDC encodes halfwidth forms, of Katakana and Hangul characters Katakana_Hangul_Halfwidth = (65381, 65500) # (ord(u"\uFF65"), ord(u"\uFFDC")) # Supplementary Ideographic Plane 20000–2FFFF Supplementary_Ideographic_Plane = ( 131072, 196607, ) # (ord(u"\U00020000"), ord(u"\U0002FFFF")) ranges = [ Hangul_Jamo, CJK_Radicals, Phags_Pa, Hangul_Syllables, CJK_Compatibility_Ideographs, CJK_Compatibility_Forms, Katakana_Hangul_Halfwidth, Supplementary_Ideographic_Plane, ] def is_cjk(character): """ Python port of Moses' code to check for CJK character. >>> CJKChars().ranges [(4352, 4607), (11904, 42191), (43072, 43135), (44032, 55215), (63744, 64255), (65072, 65103), (65381, 65500), (131072, 196607)] >>> is_cjk(u'\u33fe') True >>> is_cjk(u'\uFE5F') False :param character: The character that needs to be checked. :type character: char :return: bool """ return any( [ start <= ord(character) <= end for start, end in [ (4352, 4607), (11904, 42191), (43072, 43135), (44032, 55215), (63744, 64255), (65072, 65103), (65381, 65500), (131072, 196607), ] ] ) def xml_escape(text): """ This function transforms the input text into an "escaped" version suitable for well-formed XML formatting. Note that the default xml.sax.saxutils.escape() function don't escape some characters that Moses does so we have to manually add them to the entities dictionary. >>> input_str = ''')| & < > ' " ] [''' >>> expected_output = ''')| & < > ' " ] [''' >>> escape(input_str) == expected_output True >>> xml_escape(input_str) ')| & < > ' " ] [' :param text: The text that needs to be escaped. :type text: str :rtype: str """ return escape( text, entities={ r"'": r"'", r'"': r""", r"|": r"|", r"[": r"[", r"]": r"]", }, ) def xml_unescape(text): """ This function transforms the "escaped" version suitable for well-formed XML formatting into humanly-readable string. Note that the default xml.sax.saxutils.unescape() function don't unescape some characters that Moses does so we have to manually add them to the entities dictionary. >>> from xml.sax.saxutils import unescape >>> s = ')| & < > ' " ] [' >>> expected = ''')| & < > \' " ] [''' >>> xml_unescape(s) == expected True :param text: The text that needs to be unescaped. :type text: str :rtype: str """ return unescape( text, entities={ r"'": r"'", r""": r'"', r"|": r"|", r"[": r"[", r"]": r"]", }, ) def align_tokens(tokens, sentence): """ This module attempt to find the offsets of the tokens in *s*, as a sequence of ``(start, end)`` tuples, given the tokens and also the source string. >>> from nltk.tokenize import TreebankWordTokenizer >>> from nltk.tokenize.util import align_tokens >>> s = str("The plane, bound for St Petersburg, crashed in Egypt's " ... "Sinai desert just 23 minutes after take-off from Sharm el-Sheikh " ... "on Saturday.") >>> tokens = TreebankWordTokenizer().tokenize(s) >>> expected = [(0, 3), (4, 9), (9, 10), (11, 16), (17, 20), (21, 23), ... (24, 34), (34, 35), (36, 43), (44, 46), (47, 52), (52, 54), ... (55, 60), (61, 67), (68, 72), (73, 75), (76, 83), (84, 89), ... (90, 98), (99, 103), (104, 109), (110, 119), (120, 122), ... (123, 131), (131, 132)] >>> output = list(align_tokens(tokens, s)) >>> len(tokens) == len(expected) == len(output) # Check that length of tokens and tuples are the same. True >>> expected == list(align_tokens(tokens, s)) # Check that the output is as expected. True >>> tokens == [s[start:end] for start, end in output] # Check that the slices of the string corresponds to the tokens. True :param tokens: The list of strings that are the result of tokenization :type tokens: list(str) :param sentence: The original string :type sentence: str :rtype: list(tuple(int,int)) """ point = 0 offsets = [] for token in tokens: try: start = sentence.index(token, point) except ValueError as e: raise ValueError(f'substring "{token}" not found in "{sentence}"') from e point = start + len(token) offsets.append((start, point)) return offsets