calibre-web/vendor/babel/numbers.py

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# -*- coding: utf-8 -*-
"""
babel.numbers
~~~~~~~~~~~~~
Locale dependent formatting and parsing of numeric data.
The default locale for the functions in this module is determined by the
following environment variables, in that order:
* ``LC_NUMERIC``,
* ``LC_ALL``, and
* ``LANG``
:copyright: (c) 2013 by the Babel Team.
:license: BSD, see LICENSE for more details.
"""
# TODO:
# Padding and rounding increments in pattern:
# - http://www.unicode.org/reports/tr35/ (Appendix G.6)
from decimal import Decimal, InvalidOperation
import math
import re
from babel.core import default_locale, Locale
from babel._compat import range_type
LC_NUMERIC = default_locale('LC_NUMERIC')
def get_currency_name(currency, count=None, locale=LC_NUMERIC):
"""Return the name used by the locale for the specified currency.
>>> get_currency_name('USD', locale='en_US')
u'US Dollar'
.. versionadded:: 0.9.4
:param currency: the currency code
:param count: the optional count. If provided the currency name
will be pluralized to that number if possible.
:param locale: the `Locale` object or locale identifier
"""
loc = Locale.parse(locale)
if count is not None:
plural_form = loc.plural_form(count)
plural_names = loc._data['currency_names_plural']
if currency in plural_names:
return plural_names[currency][plural_form]
return loc.currencies.get(currency, currency)
def get_currency_symbol(currency, locale=LC_NUMERIC):
"""Return the symbol used by the locale for the specified currency.
>>> get_currency_symbol('USD', locale='en_US')
u'$'
:param currency: the currency code
:param locale: the `Locale` object or locale identifier
"""
return Locale.parse(locale).currency_symbols.get(currency, currency)
def get_decimal_symbol(locale=LC_NUMERIC):
"""Return the symbol used by the locale to separate decimal fractions.
>>> get_decimal_symbol('en_US')
u'.'
:param locale: the `Locale` object or locale identifier
"""
return Locale.parse(locale).number_symbols.get('decimal', u'.')
def get_plus_sign_symbol(locale=LC_NUMERIC):
"""Return the plus sign symbol used by the current locale.
>>> get_plus_sign_symbol('en_US')
u'+'
:param locale: the `Locale` object or locale identifier
"""
return Locale.parse(locale).number_symbols.get('plusSign', u'+')
def get_minus_sign_symbol(locale=LC_NUMERIC):
"""Return the plus sign symbol used by the current locale.
>>> get_minus_sign_symbol('en_US')
u'-'
:param locale: the `Locale` object or locale identifier
"""
return Locale.parse(locale).number_symbols.get('minusSign', u'-')
def get_exponential_symbol(locale=LC_NUMERIC):
"""Return the symbol used by the locale to separate mantissa and exponent.
>>> get_exponential_symbol('en_US')
u'E'
:param locale: the `Locale` object or locale identifier
"""
return Locale.parse(locale).number_symbols.get('exponential', u'E')
def get_group_symbol(locale=LC_NUMERIC):
"""Return the symbol used by the locale to separate groups of thousands.
>>> get_group_symbol('en_US')
u','
:param locale: the `Locale` object or locale identifier
"""
return Locale.parse(locale).number_symbols.get('group', u',')
def format_number(number, locale=LC_NUMERIC):
u"""Return the given number formatted for a specific locale.
>>> format_number(1099, locale='en_US')
u'1,099'
>>> format_number(1099, locale='de_DE')
u'1.099'
:param number: the number to format
:param locale: the `Locale` object or locale identifier
"""
# Do we really need this one?
return format_decimal(number, locale=locale)
def format_decimal(number, format=None, locale=LC_NUMERIC):
u"""Return the given decimal number formatted for a specific locale.
>>> format_decimal(1.2345, locale='en_US')
u'1.234'
>>> format_decimal(1.2346, locale='en_US')
u'1.235'
>>> format_decimal(-1.2346, locale='en_US')
u'-1.235'
>>> format_decimal(1.2345, locale='sv_SE')
u'1,234'
>>> format_decimal(1.2345, locale='de')
u'1,234'
The appropriate thousands grouping and the decimal separator are used for
each locale:
>>> format_decimal(12345.5, locale='en_US')
u'12,345.5'
:param number: the number to format
:param format:
:param locale: the `Locale` object or locale identifier
"""
locale = Locale.parse(locale)
if not format:
format = locale.decimal_formats.get(format)
pattern = parse_pattern(format)
return pattern.apply(number, locale)
def format_currency(number, currency, format=None, locale=LC_NUMERIC):
u"""Return formatted currency value.
>>> format_currency(1099.98, 'USD', locale='en_US')
u'$1,099.98'
>>> format_currency(1099.98, 'USD', locale='es_CO')
u'1.099,98\\xa0US$'
>>> format_currency(1099.98, 'EUR', locale='de_DE')
u'1.099,98\\xa0\\u20ac'
The pattern can also be specified explicitly. The currency is
placed with the '¤' sign. As the sign gets repeated the format
expands (¤ being the symbol, ¤¤ is the currency abbreviation and
¤¤¤ is the full name of the currency):
>>> format_currency(1099.98, 'EUR', u'\xa4\xa4 #,##0.00', locale='en_US')
u'EUR 1,099.98'
>>> format_currency(1099.98, 'EUR', u'#,##0.00 \xa4\xa4\xa4', locale='en_US')
u'1,099.98 euros'
:param number: the number to format
:param currency: the currency code
:param locale: the `Locale` object or locale identifier
"""
locale = Locale.parse(locale)
if not format:
format = locale.currency_formats.get(format)
pattern = parse_pattern(format)
return pattern.apply(number, locale, currency=currency)
def format_percent(number, format=None, locale=LC_NUMERIC):
"""Return formatted percent value for a specific locale.
>>> format_percent(0.34, locale='en_US')
u'34%'
>>> format_percent(25.1234, locale='en_US')
u'2,512%'
>>> format_percent(25.1234, locale='sv_SE')
u'2\\xa0512\\xa0%'
The format pattern can also be specified explicitly:
>>> format_percent(25.1234, u'#,##0\u2030', locale='en_US')
u'25,123\u2030'
:param number: the percent number to format
:param format:
:param locale: the `Locale` object or locale identifier
"""
locale = Locale.parse(locale)
if not format:
format = locale.percent_formats.get(format)
pattern = parse_pattern(format)
return pattern.apply(number, locale)
def format_scientific(number, format=None, locale=LC_NUMERIC):
"""Return value formatted in scientific notation for a specific locale.
>>> format_scientific(10000, locale='en_US')
u'1E4'
The format pattern can also be specified explicitly:
>>> format_scientific(1234567, u'##0E00', locale='en_US')
u'1.23E06'
:param number: the number to format
:param format:
:param locale: the `Locale` object or locale identifier
"""
locale = Locale.parse(locale)
if not format:
format = locale.scientific_formats.get(format)
pattern = parse_pattern(format)
return pattern.apply(number, locale)
class NumberFormatError(ValueError):
"""Exception raised when a string cannot be parsed into a number."""
def parse_number(string, locale=LC_NUMERIC):
"""Parse localized number string into an integer.
>>> parse_number('1,099', locale='en_US')
1099
>>> parse_number('1.099', locale='de_DE')
1099
When the given string cannot be parsed, an exception is raised:
>>> parse_number('1.099,98', locale='de')
Traceback (most recent call last):
...
NumberFormatError: '1.099,98' is not a valid number
:param string: the string to parse
:param locale: the `Locale` object or locale identifier
:return: the parsed number
:raise `NumberFormatError`: if the string can not be converted to a number
"""
try:
return int(string.replace(get_group_symbol(locale), ''))
except ValueError:
raise NumberFormatError('%r is not a valid number' % string)
def parse_decimal(string, locale=LC_NUMERIC):
"""Parse localized decimal string into a decimal.
>>> parse_decimal('1,099.98', locale='en_US')
Decimal('1099.98')
>>> parse_decimal('1.099,98', locale='de')
Decimal('1099.98')
When the given string cannot be parsed, an exception is raised:
>>> parse_decimal('2,109,998', locale='de')
Traceback (most recent call last):
...
NumberFormatError: '2,109,998' is not a valid decimal number
:param string: the string to parse
:param locale: the `Locale` object or locale identifier
:raise NumberFormatError: if the string can not be converted to a
decimal number
"""
locale = Locale.parse(locale)
try:
return Decimal(string.replace(get_group_symbol(locale), '')
.replace(get_decimal_symbol(locale), '.'))
except InvalidOperation:
raise NumberFormatError('%r is not a valid decimal number' % string)
PREFIX_END = r'[^0-9@#.,]'
NUMBER_TOKEN = r'[0-9@#.\-,E+]'
PREFIX_PATTERN = r"(?P<prefix>(?:'[^']*'|%s)*)" % PREFIX_END
NUMBER_PATTERN = r"(?P<number>%s+)" % NUMBER_TOKEN
SUFFIX_PATTERN = r"(?P<suffix>.*)"
number_re = re.compile(r"%s%s%s" % (PREFIX_PATTERN, NUMBER_PATTERN,
SUFFIX_PATTERN))
def split_number(value):
"""Convert a number into a (intasstring, fractionasstring) tuple"""
if isinstance(value, Decimal):
# NB can't just do text = str(value) as str repr of Decimal may be
# in scientific notation, e.g. for small numbers.
sign, digits, exp = value.as_tuple()
# build list of digits in reverse order, then reverse+join
# as per http://docs.python.org/library/decimal.html#recipes
int_part = []
frac_part = []
digits = list(map(str, digits))
# get figures after decimal point
for i in range(-exp):
# add digit if available, else 0
if digits:
frac_part.append(digits.pop())
else:
frac_part.append('0')
# add in some zeroes...
for i in range(exp):
int_part.append('0')
# and the rest
while digits:
int_part.append(digits.pop())
# if < 1, int_part must be set to '0'
if len(int_part) == 0:
int_part = '0',
if sign:
int_part.append('-')
return ''.join(reversed(int_part)), ''.join(reversed(frac_part))
text = ('%.9f' % value).rstrip('0')
if '.' in text:
a, b = text.split('.', 1)
if b == '0':
b = ''
else:
a, b = text, ''
return a, b
def bankersround(value, ndigits=0):
"""Round a number to a given precision.
Works like round() except that the round-half-even (banker's rounding)
algorithm is used instead of round-half-up.
>>> bankersround(5.5, 0)
6.0
>>> bankersround(6.5, 0)
6.0
>>> bankersround(-6.5, 0)
-6.0
>>> bankersround(1234.0, -2)
1200.0
"""
sign = int(value < 0) and -1 or 1
value = abs(value)
a, b = split_number(value)
digits = a + b
add = 0
i = len(a) + ndigits
if i < 0 or i >= len(digits):
pass
elif digits[i] > '5':
add = 1
elif digits[i] == '5' and digits[i-1] in '13579':
add = 1
elif digits[i] == '5': # previous digit is even
# We round up unless all following digits are zero.
for j in range_type(i + 1, len(digits)):
if digits[j] != '0':
add = 1
break
scale = 10**ndigits
if isinstance(value, Decimal):
return Decimal(int(value * scale + add)) / scale * sign
else:
return float(int(value * scale + add)) / scale * sign
def parse_grouping(p):
"""Parse primary and secondary digit grouping
>>> parse_grouping('##')
(1000, 1000)
>>> parse_grouping('#,###')
(3, 3)
>>> parse_grouping('#,####,###')
(3, 4)
"""
width = len(p)
g1 = p.rfind(',')
if g1 == -1:
return 1000, 1000
g1 = width - g1 - 1
g2 = p[:-g1 - 1].rfind(',')
if g2 == -1:
return g1, g1
g2 = width - g1 - g2 - 2
return g1, g2
def parse_pattern(pattern):
"""Parse number format patterns"""
if isinstance(pattern, NumberPattern):
return pattern
def _match_number(pattern):
rv = number_re.search(pattern)
if rv is None:
raise ValueError('Invalid number pattern %r' % pattern)
return rv.groups()
# Do we have a negative subpattern?
if ';' in pattern:
pattern, neg_pattern = pattern.split(';', 1)
pos_prefix, number, pos_suffix = _match_number(pattern)
neg_prefix, _, neg_suffix = _match_number(neg_pattern)
else:
pos_prefix, number, pos_suffix = _match_number(pattern)
neg_prefix = '-' + pos_prefix
neg_suffix = pos_suffix
if 'E' in number:
number, exp = number.split('E', 1)
else:
exp = None
if '@' in number:
if '.' in number and '0' in number:
raise ValueError('Significant digit patterns can not contain '
'"@" or "0"')
if '.' in number:
integer, fraction = number.rsplit('.', 1)
else:
integer = number
fraction = ''
def parse_precision(p):
"""Calculate the min and max allowed digits"""
min = max = 0
for c in p:
if c in '@0':
min += 1
max += 1
elif c == '#':
max += 1
elif c == ',':
continue
else:
break
return min, max
int_prec = parse_precision(integer)
frac_prec = parse_precision(fraction)
if exp:
frac_prec = parse_precision(integer+fraction)
exp_plus = exp.startswith('+')
exp = exp.lstrip('+')
exp_prec = parse_precision(exp)
else:
exp_plus = None
exp_prec = None
grouping = parse_grouping(integer)
return NumberPattern(pattern, (pos_prefix, neg_prefix),
(pos_suffix, neg_suffix), grouping,
int_prec, frac_prec,
exp_prec, exp_plus)
class NumberPattern(object):
def __init__(self, pattern, prefix, suffix, grouping,
int_prec, frac_prec, exp_prec, exp_plus):
self.pattern = pattern
self.prefix = prefix
self.suffix = suffix
self.grouping = grouping
self.int_prec = int_prec
self.frac_prec = frac_prec
self.exp_prec = exp_prec
self.exp_plus = exp_plus
if '%' in ''.join(self.prefix + self.suffix):
self.scale = 100
elif u'' in ''.join(self.prefix + self.suffix):
self.scale = 1000
else:
self.scale = 1
def __repr__(self):
return '<%s %r>' % (type(self).__name__, self.pattern)
def apply(self, value, locale, currency=None):
if isinstance(value, float):
value = Decimal(str(value))
value *= self.scale
is_negative = int(value < 0)
if self.exp_prec: # Scientific notation
value = abs(value)
if value:
exp = int(math.floor(math.log(value, 10)))
else:
exp = 0
# Minimum number of integer digits
if self.int_prec[0] == self.int_prec[1]:
exp -= self.int_prec[0] - 1
# Exponent grouping
elif self.int_prec[1]:
exp = int(exp / self.int_prec[1]) * self.int_prec[1]
if not isinstance(value, Decimal):
value = float(value)
if exp < 0:
value = value * 10**(-exp)
else:
value = value / 10**exp
exp_sign = ''
if exp < 0:
exp_sign = get_minus_sign_symbol(locale)
elif self.exp_plus:
exp_sign = get_plus_sign_symbol(locale)
exp = abs(exp)
number = u'%s%s%s%s' % \
(self._format_sigdig(value, self.frac_prec[0],
self.frac_prec[1]),
get_exponential_symbol(locale), exp_sign,
self._format_int(str(exp), self.exp_prec[0],
self.exp_prec[1], locale))
elif '@' in self.pattern: # Is it a siginificant digits pattern?
text = self._format_sigdig(abs(value),
self.int_prec[0],
self.int_prec[1])
if '.' in text:
a, b = text.split('.')
a = self._format_int(a, 0, 1000, locale)
if b:
b = get_decimal_symbol(locale) + b
number = a + b
else:
number = self._format_int(text, 0, 1000, locale)
else: # A normal number pattern
a, b = split_number(bankersround(abs(value),
self.frac_prec[1]))
b = b or '0'
a = self._format_int(a, self.int_prec[0],
self.int_prec[1], locale)
b = self._format_frac(b, locale)
number = a + b
retval = u'%s%s%s' % (self.prefix[is_negative], number,
self.suffix[is_negative])
if u'¤' in retval:
retval = retval.replace(u'¤¤¤',
get_currency_name(currency, value, locale))
retval = retval.replace(u'¤¤', currency.upper())
retval = retval.replace(u'¤', get_currency_symbol(currency, locale))
return retval
def _format_sigdig(self, value, min, max):
"""Convert value to a string.
The resulting string will contain between (min, max) number of
significant digits.
"""
a, b = split_number(value)
ndecimals = len(a)
if a == '0' and b != '':
ndecimals = 0
while b.startswith('0'):
b = b[1:]
ndecimals -= 1
a, b = split_number(bankersround(value, max - ndecimals))
digits = len((a + b).lstrip('0'))
if not digits:
digits = 1
# Figure out if we need to add any trailing '0':s
if len(a) >= max and a != '0':
return a
if digits < min:
b += ('0' * (min - digits))
if b:
return '%s.%s' % (a, b)
return a
def _format_int(self, value, min, max, locale):
width = len(value)
if width < min:
value = '0' * (min - width) + value
gsize = self.grouping[0]
ret = ''
symbol = get_group_symbol(locale)
while len(value) > gsize:
ret = symbol + value[-gsize:] + ret
value = value[:-gsize]
gsize = self.grouping[1]
return value + ret
def _format_frac(self, value, locale):
min, max = self.frac_prec
if len(value) < min:
value += ('0' * (min - len(value)))
if max == 0 or (min == 0 and int(value) == 0):
return ''
width = len(value)
while len(value) > min and value[-1] == '0':
value = value[:-1]
return get_decimal_symbol(locale) + value