396 lines
12 KiB
Python
396 lines
12 KiB
Python
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import importlib
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from codecs import IncrementalDecoder
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from collections import Counter
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from functools import lru_cache
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from typing import Counter as TypeCounter, Dict, List, Optional, Tuple
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from .constant import (
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FREQUENCIES,
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KO_NAMES,
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LANGUAGE_SUPPORTED_COUNT,
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TOO_SMALL_SEQUENCE,
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ZH_NAMES,
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)
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from .md import is_suspiciously_successive_range
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from .models import CoherenceMatches
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from .utils import (
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is_accentuated,
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is_latin,
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is_multi_byte_encoding,
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is_unicode_range_secondary,
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unicode_range,
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)
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def encoding_unicode_range(iana_name: str) -> List[str]:
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"""
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Return associated unicode ranges in a single byte code page.
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"""
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if is_multi_byte_encoding(iana_name):
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raise IOError("Function not supported on multi-byte code page")
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decoder = importlib.import_module(
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"encodings.{}".format(iana_name)
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).IncrementalDecoder
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p: IncrementalDecoder = decoder(errors="ignore")
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seen_ranges: Dict[str, int] = {}
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character_count: int = 0
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for i in range(0x40, 0xFF):
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chunk: str = p.decode(bytes([i]))
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if chunk:
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character_range: Optional[str] = unicode_range(chunk)
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if character_range is None:
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continue
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if is_unicode_range_secondary(character_range) is False:
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if character_range not in seen_ranges:
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seen_ranges[character_range] = 0
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seen_ranges[character_range] += 1
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character_count += 1
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return sorted(
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[
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character_range
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for character_range in seen_ranges
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if seen_ranges[character_range] / character_count >= 0.15
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]
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)
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def unicode_range_languages(primary_range: str) -> List[str]:
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"""
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Return inferred languages used with a unicode range.
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"""
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languages: List[str] = []
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for language, characters in FREQUENCIES.items():
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for character in characters:
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if unicode_range(character) == primary_range:
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languages.append(language)
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break
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return languages
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@lru_cache()
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def encoding_languages(iana_name: str) -> List[str]:
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"""
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Single-byte encoding language association. Some code page are heavily linked to particular language(s).
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This function does the correspondence.
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"""
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unicode_ranges: List[str] = encoding_unicode_range(iana_name)
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primary_range: Optional[str] = None
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for specified_range in unicode_ranges:
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if "Latin" not in specified_range:
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primary_range = specified_range
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break
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if primary_range is None:
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return ["Latin Based"]
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return unicode_range_languages(primary_range)
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@lru_cache()
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def mb_encoding_languages(iana_name: str) -> List[str]:
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"""
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Multi-byte encoding language association. Some code page are heavily linked to particular language(s).
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This function does the correspondence.
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"""
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if (
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iana_name.startswith("shift_")
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or iana_name.startswith("iso2022_jp")
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or iana_name.startswith("euc_j")
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or iana_name == "cp932"
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):
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return ["Japanese"]
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if iana_name.startswith("gb") or iana_name in ZH_NAMES:
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return ["Chinese"]
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if iana_name.startswith("iso2022_kr") or iana_name in KO_NAMES:
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return ["Korean"]
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return []
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@lru_cache(maxsize=LANGUAGE_SUPPORTED_COUNT)
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def get_target_features(language: str) -> Tuple[bool, bool]:
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"""
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Determine main aspects from a supported language if it contains accents and if is pure Latin.
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"""
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target_have_accents: bool = False
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target_pure_latin: bool = True
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for character in FREQUENCIES[language]:
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if not target_have_accents and is_accentuated(character):
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target_have_accents = True
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if target_pure_latin and is_latin(character) is False:
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target_pure_latin = False
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return target_have_accents, target_pure_latin
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def alphabet_languages(
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characters: List[str], ignore_non_latin: bool = False
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) -> List[str]:
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"""
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Return associated languages associated to given characters.
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"""
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languages: List[Tuple[str, float]] = []
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source_have_accents = any(is_accentuated(character) for character in characters)
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for language, language_characters in FREQUENCIES.items():
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target_have_accents, target_pure_latin = get_target_features(language)
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if ignore_non_latin and target_pure_latin is False:
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continue
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if target_have_accents is False and source_have_accents:
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continue
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character_count: int = len(language_characters)
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character_match_count: int = len(
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[c for c in language_characters if c in characters]
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)
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ratio: float = character_match_count / character_count
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if ratio >= 0.2:
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languages.append((language, ratio))
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languages = sorted(languages, key=lambda x: x[1], reverse=True)
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return [compatible_language[0] for compatible_language in languages]
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def characters_popularity_compare(
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language: str, ordered_characters: List[str]
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) -> float:
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"""
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Determine if a ordered characters list (by occurrence from most appearance to rarest) match a particular language.
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The result is a ratio between 0. (absolutely no correspondence) and 1. (near perfect fit).
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Beware that is function is not strict on the match in order to ease the detection. (Meaning close match is 1.)
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"""
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if language not in FREQUENCIES:
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raise ValueError("{} not available".format(language))
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character_approved_count: int = 0
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FREQUENCIES_language_set = set(FREQUENCIES[language])
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ordered_characters_count: int = len(ordered_characters)
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target_language_characters_count: int = len(FREQUENCIES[language])
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large_alphabet: bool = target_language_characters_count > 26
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for character, character_rank in zip(
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ordered_characters, range(0, ordered_characters_count)
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):
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if character not in FREQUENCIES_language_set:
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continue
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character_rank_in_language: int = FREQUENCIES[language].index(character)
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expected_projection_ratio: float = (
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target_language_characters_count / ordered_characters_count
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)
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character_rank_projection: int = int(character_rank * expected_projection_ratio)
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if (
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large_alphabet is False
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and abs(character_rank_projection - character_rank_in_language) > 4
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):
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continue
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if (
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large_alphabet is True
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and abs(character_rank_projection - character_rank_in_language)
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< target_language_characters_count / 3
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):
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character_approved_count += 1
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continue
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characters_before_source: List[str] = FREQUENCIES[language][
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0:character_rank_in_language
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]
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characters_after_source: List[str] = FREQUENCIES[language][
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character_rank_in_language:
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]
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characters_before: List[str] = ordered_characters[0:character_rank]
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characters_after: List[str] = ordered_characters[character_rank:]
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before_match_count: int = len(
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set(characters_before) & set(characters_before_source)
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)
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after_match_count: int = len(
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set(characters_after) & set(characters_after_source)
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)
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if len(characters_before_source) == 0 and before_match_count <= 4:
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character_approved_count += 1
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continue
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if len(characters_after_source) == 0 and after_match_count <= 4:
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character_approved_count += 1
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continue
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if (
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before_match_count / len(characters_before_source) >= 0.4
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or after_match_count / len(characters_after_source) >= 0.4
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):
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character_approved_count += 1
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continue
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return character_approved_count / len(ordered_characters)
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def alpha_unicode_split(decoded_sequence: str) -> List[str]:
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"""
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Given a decoded text sequence, return a list of str. Unicode range / alphabet separation.
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Ex. a text containing English/Latin with a bit a Hebrew will return two items in the resulting list;
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One containing the latin letters and the other hebrew.
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"""
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layers: Dict[str, str] = {}
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for character in decoded_sequence:
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if character.isalpha() is False:
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continue
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character_range: Optional[str] = unicode_range(character)
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if character_range is None:
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continue
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layer_target_range: Optional[str] = None
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for discovered_range in layers:
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if (
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is_suspiciously_successive_range(discovered_range, character_range)
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is False
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):
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layer_target_range = discovered_range
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break
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if layer_target_range is None:
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layer_target_range = character_range
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if layer_target_range not in layers:
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layers[layer_target_range] = character.lower()
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continue
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layers[layer_target_range] += character.lower()
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return list(layers.values())
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def merge_coherence_ratios(results: List[CoherenceMatches]) -> CoherenceMatches:
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"""
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This function merge results previously given by the function coherence_ratio.
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The return type is the same as coherence_ratio.
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"""
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per_language_ratios: Dict[str, List[float]] = {}
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for result in results:
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for sub_result in result:
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language, ratio = sub_result
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if language not in per_language_ratios:
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per_language_ratios[language] = [ratio]
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continue
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per_language_ratios[language].append(ratio)
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merge = [
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(
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language,
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round(
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sum(per_language_ratios[language]) / len(per_language_ratios[language]),
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4,
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),
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)
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for language in per_language_ratios
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]
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return sorted(merge, key=lambda x: x[1], reverse=True)
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def filter_alt_coherence_matches(results: CoherenceMatches) -> CoherenceMatches:
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"""
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We shall NOT return "English—" in CoherenceMatches because it is an alternative
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of "English". This function only keeps the best match and remove the em-dash in it.
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"""
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index_results: Dict[str, List[float]] = dict()
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for result in results:
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language, ratio = result
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no_em_name: str = language.replace("—", "")
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if no_em_name not in index_results:
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index_results[no_em_name] = []
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index_results[no_em_name].append(ratio)
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if any(len(index_results[e]) > 1 for e in index_results):
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filtered_results: CoherenceMatches = []
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for language in index_results:
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filtered_results.append((language, max(index_results[language])))
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return filtered_results
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return results
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@lru_cache(maxsize=2048)
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def coherence_ratio(
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decoded_sequence: str, threshold: float = 0.1, lg_inclusion: Optional[str] = None
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) -> CoherenceMatches:
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"""
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Detect ANY language that can be identified in given sequence. The sequence will be analysed by layers.
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A layer = Character extraction by alphabets/ranges.
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"""
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results: List[Tuple[str, float]] = []
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ignore_non_latin: bool = False
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sufficient_match_count: int = 0
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lg_inclusion_list = lg_inclusion.split(",") if lg_inclusion is not None else []
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if "Latin Based" in lg_inclusion_list:
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ignore_non_latin = True
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lg_inclusion_list.remove("Latin Based")
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for layer in alpha_unicode_split(decoded_sequence):
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sequence_frequencies: TypeCounter[str] = Counter(layer)
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most_common = sequence_frequencies.most_common()
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character_count: int = sum(o for c, o in most_common)
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if character_count <= TOO_SMALL_SEQUENCE:
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continue
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popular_character_ordered: List[str] = [c for c, o in most_common]
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for language in lg_inclusion_list or alphabet_languages(
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popular_character_ordered, ignore_non_latin
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):
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ratio: float = characters_popularity_compare(
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language, popular_character_ordered
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)
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if ratio < threshold:
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continue
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elif ratio >= 0.8:
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sufficient_match_count += 1
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results.append((language, round(ratio, 4)))
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if sufficient_match_count >= 3:
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break
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return sorted(
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filter_alt_coherence_matches(results), key=lambda x: x[1], reverse=True
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)
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