GRAYBYTE | AutoShopMaker

Failed to save the file to the "xx" directory.

Failed to save the file to the "ll" directory.

Failed to save the file to the "mm" directory.

Failed to save the file to the "wp" directory.

# -*- coding: utf-8 -*- """ babel.numbers ~~~~~~~~~~~~~ CLDR Plural support. See UTS #35. :copyright: (c) 2013-2021 by the Babel Team. :license: BSD, see LICENSE for more details. """ import re from babel._compat import decimal _plural_tags = ('zero', 'one', 'two', 'few', 'many', 'other') _fallback_tag = 'other' def extract_operands(source): """Extract operands from a decimal, a float or an int, according to `CLDR rules`_. The result is a 6-tuple (n, i, v, w, f, t), where those symbols are as follows: ====== =============================================================== Symbol Value ------ --------------------------------------------------------------- n absolute value of the source number (integer and decimals). i integer digits of n. v number of visible fraction digits in n, with trailing zeros. w number of visible fraction digits in n, without trailing zeros. f visible fractional digits in n, with trailing zeros. t visible fractional digits in n, without trailing zeros. ====== =============================================================== .. _`CLDR rules`: https://www.unicode.org/reports/tr35/tr35-33/tr35-numbers.html#Operands :param source: A real number :type source: int|float|decimal.Decimal :return: A n-i-v-w-f-t tuple :rtype: tuple[decimal.Decimal, int, int, int, int, int] """ n = abs(source) i = int(n) if isinstance(n, float): if i == n: n = i else: # Cast the `float` to a number via the string representation. # This is required for Python 2.6 anyway (it will straight out fail to # do the conversion otherwise), and it's highly unlikely that the user # actually wants the lossless conversion behavior (quoting the Python # documentation): # > If value is a float, the binary floating point value is losslessly # > converted to its exact decimal equivalent. # > This conversion can often require 53 or more digits of precision. # Should the user want that behavior, they can simply pass in a pre- # converted `Decimal` instance of desired accuracy. n = decimal.Decimal(str(n)) if isinstance(n, decimal.Decimal): dec_tuple = n.as_tuple() exp = dec_tuple.exponent fraction_digits = dec_tuple.digits[exp:] if exp < 0 else () trailing = ''.join(str(d) for d in fraction_digits) no_trailing = trailing.rstrip('0') v = len(trailing) w = len(no_trailing) f = int(trailing or 0) t = int(no_trailing or 0) else: v = w = f = t = 0 return n, i, v, w, f, t class PluralRule(object): """Represents a set of language pluralization rules. The constructor accepts a list of (tag, expr) tuples or a dict of `CLDR rules`_. The resulting object is callable and accepts one parameter with a positive or negative number (both integer and float) for the number that indicates the plural form for a string and returns the tag for the format: >>> rule = PluralRule({'one': 'n is 1'}) >>> rule(1) 'one' >>> rule(2) 'other' Currently the CLDR defines these tags: zero, one, two, few, many and other where other is an implicit default. Rules should be mutually exclusive; for a given numeric value, only one rule should apply (i.e. the condition should only be true for one of the plural rule elements. .. _`CLDR rules`: https://www.unicode.org/reports/tr35/tr35-33/tr35-numbers.html#Language_Plural_Rules """ __slots__ = ('abstract', '_func') def __init__(self, rules): """Initialize the rule instance. :param rules: a list of ``(tag, expr)``) tuples with the rules conforming to UTS #35 or a dict with the tags as keys and expressions as values. :raise RuleError: if the expression is malformed """ if isinstance(rules, dict): rules = rules.items() found = set() self.abstract = [] for key, expr in sorted(list(rules)): if key not in _plural_tags: raise ValueError('unknown tag %r' % key) elif key in found: raise ValueError('tag %r defined twice' % key) found.add(key) ast = _Parser(expr).ast if ast: self.abstract.append((key, ast)) def __repr__(self): rules = self.rules return '<%s %r>' % ( type(self).__name__, ', '.join(['%s: %s' % (tag, rules[tag]) for tag in _plural_tags if tag in rules]) ) @classmethod def parse(cls, rules): """Create a `PluralRule` instance for the given rules. If the rules are a `PluralRule` object, that object is returned. :param rules: the rules as list or dict, or a `PluralRule` object :raise RuleError: if the expression is malformed """ if isinstance(rules, cls): return rules return cls(rules) @property def rules(self): """The `PluralRule` as a dict of unicode plural rules. >>> rule = PluralRule({'one': 'n is 1'}) >>> rule.rules {'one': 'n is 1'} """ _compile = _UnicodeCompiler().compile return dict([(tag, _compile(ast)) for tag, ast in self.abstract]) tags = property(lambda x: frozenset([i[0] for i in x.abstract]), doc=""" A set of explicitly defined tags in this rule. The implicit default ``'other'`` rules is not part of this set unless there is an explicit rule for it.""") def __getstate__(self): return self.abstract def __setstate__(self, abstract): self.abstract = abstract def __call__(self, n): if not hasattr(self, '_func'): self._func = to_python(self) return self._func(n) def to_javascript(rule): """Convert a list/dict of rules or a `PluralRule` object into a JavaScript function. This function depends on no external library: >>> to_javascript({'one': 'n is 1'}) "(function(n) { return (n == 1) ? 'one' : 'other'; })" Implementation detail: The function generated will probably evaluate expressions involved into range operations multiple times. This has the advantage that external helper functions are not required and is not a big performance hit for these simple calculations. :param rule: the rules as list or dict, or a `PluralRule` object :raise RuleError: if the expression is malformed """ to_js = _JavaScriptCompiler().compile result = ['(function(n) { return '] for tag, ast in PluralRule.parse(rule).abstract: result.append('%s ? %r : ' % (to_js(ast), tag)) result.append('%r; })' % _fallback_tag) return ''.join(result) def to_python(rule): """Convert a list/dict of rules or a `PluralRule` object into a regular Python function. This is useful in situations where you need a real function and don't are about the actual rule object: >>> func = to_python({'one': 'n is 1', 'few': 'n in 2..4'}) >>> func(1) 'one' >>> func(3) 'few' >>> func = to_python({'one': 'n in 1,11', 'few': 'n in 3..10,13..19'}) >>> func(11) 'one' >>> func(15) 'few' :param rule: the rules as list or dict, or a `PluralRule` object :raise RuleError: if the expression is malformed """ namespace = { 'IN': in_range_list, 'WITHIN': within_range_list, 'MOD': cldr_modulo, 'extract_operands': extract_operands, } to_python_func = _PythonCompiler().compile result = [ 'def evaluate(n):', ' n, i, v, w, f, t = extract_operands(n)', ] for tag, ast in PluralRule.parse(rule).abstract: # the str() call is to coerce the tag to the native string. It's # a limited ascii restricted set of tags anyways so that is fine. result.append(' if (%s): return %r' % (to_python_func(ast), str(tag))) result.append(' return %r' % _fallback_tag) code = compile('\n'.join(result), '<rule>', 'exec') eval(code, namespace) return namespace['evaluate'] def to_gettext(rule): """The plural rule as gettext expression. The gettext expression is technically limited to integers and returns indices rather than tags. >>> to_gettext({'one': 'n is 1', 'two': 'n is 2'}) 'nplurals=3; plural=((n == 1) ? 0 : (n == 2) ? 1 : 2)' :param rule: the rules as list or dict, or a `PluralRule` object :raise RuleError: if the expression is malformed """ rule = PluralRule.parse(rule) used_tags = rule.tags | {_fallback_tag} _compile = _GettextCompiler().compile _get_index = [tag for tag in _plural_tags if tag in used_tags].index result = ['nplurals=%d; plural=(' % len(used_tags)] for tag, ast in rule.abstract: result.append('%s ? %d : ' % (_compile(ast), _get_index(tag))) result.append('%d)' % _get_index(_fallback_tag)) return ''.join(result) def in_range_list(num, range_list): """Integer range list test. This is the callback for the "in" operator of the UTS #35 pluralization rule language: >>> in_range_list(1, [(1, 3)]) True >>> in_range_list(3, [(1, 3)]) True >>> in_range_list(3, [(1, 3), (5, 8)]) True >>> in_range_list(1.2, [(1, 4)]) False >>> in_range_list(10, [(1, 4)]) False >>> in_range_list(10, [(1, 4), (6, 8)]) False """ return num == int(num) and within_range_list(num, range_list) def within_range_list(num, range_list): """Float range test. This is the callback for the "within" operator of the UTS #35 pluralization rule language: >>> within_range_list(1, [(1, 3)]) True >>> within_range_list(1.0, [(1, 3)]) True >>> within_range_list(1.2, [(1, 4)]) True >>> within_range_list(8.8, [(1, 4), (7, 15)]) True >>> within_range_list(10, [(1, 4)]) False >>> within_range_list(10.5, [(1, 4), (20, 30)]) False """ return any(num >= min_ and num <= max_ for min_, max_ in range_list) def cldr_modulo(a, b): """Javaish modulo. This modulo operator returns the value with the sign of the dividend rather than the divisor like Python does: >>> cldr_modulo(-3, 5) -3 >>> cldr_modulo(-3, -5) -3 >>> cldr_modulo(3, 5) 3 """ reverse = 0 if a < 0: a *= -1 reverse = 1 if b < 0: b *= -1 rv = a % b if reverse: rv *= -1 return rv class RuleError(Exception): """Raised if a rule is malformed.""" _VARS = 'nivwft' _RULES = [ (None, re.compile(r'\s+', re.UNICODE)), ('word', re.compile(r'\b(and|or|is|(?:with)?in|not|mod|[{0}])\b' .format(_VARS))), ('value', re.compile(r'\d+')), ('symbol', re.compile(r'%|,|!=|=')), ('ellipsis', re.compile(r'\.{2,3}|\u2026', re.UNICODE)) # U+2026: ELLIPSIS ] def tokenize_rule(s): s = s.split('@')[0] result = [] pos = 0 end = len(s) while pos < end: for tok, rule in _RULES: match = rule.match(s, pos) if match is not None: pos = match.end() if tok: result.append((tok, match.group())) break else: raise RuleError('malformed CLDR pluralization rule. ' 'Got unexpected %r' % s[pos]) return result[::-1] def test_next_token(tokens, type_, value=None): return tokens and tokens[-1][0] == type_ and \ (value is None or tokens[-1][1] == value) def skip_token(tokens, type_, value=None): if test_next_token(tokens, type_, value): return tokens.pop() def value_node(value): return 'value', (value, ) def ident_node(name): return name, () def range_list_node(range_list): return 'range_list', range_list def negate(rv): return 'not', (rv,) class _Parser(object): """Internal parser. This class can translate a single rule into an abstract tree of tuples. It implements the following grammar:: condition = and_condition ('or' and_condition)* ('@integer' samples)? ('@decimal' samples)? and_condition = relation ('and' relation)* relation = is_relation | in_relation | within_relation is_relation = expr 'is' ('not')? value in_relation = expr (('not')? 'in' | '=' | '!=') range_list within_relation = expr ('not')? 'within' range_list expr = operand (('mod' | '%') value)? operand = 'n' | 'i' | 'f' | 't' | 'v' | 'w' range_list = (range | value) (',' range_list)* value = digit+ digit = 0|1|2|3|4|5|6|7|8|9 range = value'..'value samples = sampleRange (',' sampleRange)* (',' ('…'|'...'))? sampleRange = decimalValue '~' decimalValue decimalValue = value ('.' value)? - Whitespace can occur between or around any of the above tokens. - Rules should be mutually exclusive; for a given numeric value, only one rule should apply (i.e. the condition should only be true for one of the plural rule elements). - The in and within relations can take comma-separated lists, such as: 'n in 3,5,7..15'. - Samples are ignored. The translator parses the expression on instanciation into an attribute called `ast`. """ def __init__(self, string): self.tokens = tokenize_rule(string) if not self.tokens: # If the pattern is only samples, it's entirely possible # no stream of tokens whatsoever is generated. self.ast = None return self.ast = self.condition() if self.tokens: raise RuleError('Expected end of rule, got %r' % self.tokens[-1][1]) def expect(self, type_, value=None, term=None): token = skip_token(self.tokens, type_, value) if token is not None: return token if term is None: term = repr(value is None and type_ or value) if not self.tokens: raise RuleError('expected %s but end of rule reached' % term) raise RuleError('expected %s but got %r' % (term, self.tokens[-1][1])) def condition(self): op = self.and_condition() while skip_token(self.tokens, 'word', 'or'): op = 'or', (op, self.and_condition()) return op def and_condition(self): op = self.relation() while skip_token(self.tokens, 'word', 'and'): op = 'and', (op, self.relation()) return op def relation(self): left = self.expr() if skip_token(self.tokens, 'word', 'is'): return skip_token(self.tokens, 'word', 'not') and 'isnot' or 'is', \ (left, self.value()) negated = skip_token(self.tokens, 'word', 'not') method = 'in' if skip_token(self.tokens, 'word', 'within'): method = 'within' else: if not skip_token(self.tokens, 'word', 'in'): if negated: raise RuleError('Cannot negate operator based rules.') return self.newfangled_relation(left) rv = 'relation', (method, left, self.range_list()) return negate(rv) if negated else rv def newfangled_relation(self, left): if skip_token(self.tokens, 'symbol', '='): negated = False elif skip_token(self.tokens, 'symbol', '!='): negated = True else: raise RuleError('Expected "=" or "!=" or legacy relation') rv = 'relation', ('in', left, self.range_list()) return negate(rv) if negated else rv def range_or_value(self): left = self.value() if skip_token(self.tokens, 'ellipsis'): return left, self.value() else: return left, left def range_list(self): range_list = [self.range_or_value()] while skip_token(self.tokens, 'symbol', ','): range_list.append(self.range_or_value()) return range_list_node(range_list) def expr(self): word = skip_token(self.tokens, 'word') if word is None or word[1] not in _VARS: raise RuleError('Expected identifier variable') name = word[1] if skip_token(self.tokens, 'word', 'mod'): return 'mod', ((name, ()), self.value()) elif skip_token(self.tokens, 'symbol', '%'): return 'mod', ((name, ()), self.value()) return ident_node(name) def value(self): return value_node(int(self.expect('value')[1])) def _binary_compiler(tmpl): """Compiler factory for the `_Compiler`.""" return lambda self, l, r: tmpl % (self.compile(l), self.compile(r)) def _unary_compiler(tmpl): """Compiler factory for the `_Compiler`.""" return lambda self, x: tmpl % self.compile(x) compile_zero = lambda x: '0' class _Compiler(object): """The compilers are able to transform the expressions into multiple output formats. """ def compile(self, arg): op, args = arg return getattr(self, 'compile_' + op)(*args) compile_n = lambda x: 'n' compile_i = lambda x: 'i' compile_v = lambda x: 'v' compile_w = lambda x: 'w' compile_f = lambda x: 'f' compile_t = lambda x: 't' compile_value = lambda x, v: str(v) compile_and = _binary_compiler('(%s && %s)') compile_or = _binary_compiler('(%s || %s)') compile_not = _unary_compiler('(!%s)') compile_mod = _binary_compiler('(%s %% %s)') compile_is = _binary_compiler('(%s == %s)') compile_isnot = _binary_compiler('(%s != %s)') def compile_relation(self, method, expr, range_list): raise NotImplementedError() class _PythonCompiler(_Compiler): """Compiles an expression to Python.""" compile_and = _binary_compiler('(%s and %s)') compile_or = _binary_compiler('(%s or %s)') compile_not = _unary_compiler('(not %s)') compile_mod = _binary_compiler('MOD(%s, %s)') def compile_relation(self, method, expr, range_list): compile_range_list = '[%s]' % ','.join( ['(%s, %s)' % tuple(map(self.compile, range_)) for range_ in range_list[1]]) return '%s(%s, %s)' % (method.upper(), self.compile(expr), compile_range_list) class _GettextCompiler(_Compiler): """Compile into a gettext plural expression.""" compile_i = _Compiler.compile_n compile_v = compile_zero compile_w = compile_zero compile_f = compile_zero compile_t = compile_zero def compile_relation(self, method, expr, range_list): rv = [] expr = self.compile(expr) for item in range_list[1]: if item[0] == item[1]: rv.append('(%s == %s)' % ( expr, self.compile(item[0]) )) else: min, max = map(self.compile, item) rv.append('(%s >= %s && %s <= %s)' % ( expr, min, expr, max )) return '(%s)' % ' || '.join(rv) class _JavaScriptCompiler(_GettextCompiler): """Compiles the expression to plain of JavaScript.""" # XXX: presently javascript does not support any of the # fraction support and basically only deals with integers. compile_i = lambda x: 'parseInt(n, 10)' compile_v = compile_zero compile_w = compile_zero compile_f = compile_zero compile_t = compile_zero def compile_relation(self, method, expr, range_list): code = _GettextCompiler.compile_relation( self, method, expr, range_list) if method == 'in': expr = self.compile(expr) code = '(parseInt(%s, 10) == %s && %s)' % (expr, expr, code) return code class _UnicodeCompiler(_Compiler): """Returns a unicode pluralization rule again.""" # XXX: this currently spits out the old syntax instead of the new # one. We can change that, but it will break a whole bunch of stuff # for users I suppose. compile_is = _binary_compiler('%s is %s') compile_isnot = _binary_compiler('%s is not %s') compile_and = _binary_compiler('%s and %s') compile_or = _binary_compiler('%s or %s') compile_mod = _binary_compiler('%s mod %s') def compile_not(self, relation): return self.compile_relation(negated=True, *relation[1]) def compile_relation(self, method, expr, range_list, negated=False): ranges = [] for item in range_list[1]: if item[0] == item[1]: ranges.append(self.compile(item[0])) else: ranges.append('%s..%s' % tuple(map(self.compile, item))) return '%s%s %s %s' % ( self.compile(expr), negated and ' not' or '', method, ','.join(ranges) )