Lib/string.py - platform/external/python/cpython3 - Gitiles

 """A collection of string constants.

 Public module variables:

 whitespace -- a string containing all ASCII whitespace
 ascii_lowercase -- a string containing all ASCII lowercase letters
 ascii_uppercase -- a string containing all ASCII uppercase letters
 ascii_letters -- a string containing all ASCII letters
 digits -- a string containing all ASCII decimal digits
 hexdigits -- a string containing all ASCII hexadecimal digits
 octdigits -- a string containing all ASCII octal digits
 punctuation -- a string containing all ASCII punctuation characters
 printable -- a string containing all ASCII characters considered printable

 """

 # Some strings for ctype-style character classification
 whitespace = ' \t\n\r\v\f'
 ascii_lowercase = 'abcdefghijklmnopqrstuvwxyz'
 ascii_uppercase = 'ABCDEFGHIJKLMNOPQRSTUVWXYZ'
 ascii_letters = ascii_lowercase + ascii_uppercase
 digits = '0123456789'
 hexdigits = digits + 'abcdef' + 'ABCDEF'
 octdigits = '01234567'
 punctuation = """!"#$%&'()*+,-./:;<=>?@[\]^_`{|}~"""
 printable = digits + ascii_letters + punctuation + whitespace

 # Functions which aren't available as string methods.

 # Capitalize the words in a string, e.g. " aBc  dEf " -> "Abc Def".
 def capwords(s, sep=None):
     """capwords(s, [sep]) -> string

     Split the argument into words using split, capitalize each
     word using capitalize, and join the capitalized words using
     join. Note that this replaces runs of whitespace characters by
     a single space.

     """
     return (sep or ' ').join([x.capitalize() for x in s.split(sep)])


 ####################################################################
 import re as _re

 class _multimap:
     """Helper class for combining multiple mappings.

     Used by .{safe_,}substitute() to combine the mapping and keyword
     arguments.
     """
     def __init__(self, primary, secondary):
         self._primary = primary
         self._secondary = secondary

     def __getitem__(self, key):
         try:
             return self._primary[key]
         except KeyError:
             return self._secondary[key]


 class _TemplateMetaclass(type):
     pattern = r"""
     %(delim)s(?:
       (?P<escaped>%(delim)s) |   # Escape sequence of two delimiters
       (?P<named>%(id)s)      |   # delimiter and a Python identifier
       {(?P<braced>%(id)s)}   |   # delimiter and a braced identifier
       (?P<invalid>)              # Other ill-formed delimiter exprs
     )
     """

     def __init__(cls, name, bases, dct):
         super(_TemplateMetaclass, cls).__init__(name, bases, dct)
         if 'pattern' in dct:
             pattern = cls.pattern
         else:
             pattern = _TemplateMetaclass.pattern % {
                 'delim' : _re.escape(cls.delimiter),
                 'id'    : cls.idpattern,
                 }
         cls.pattern = _re.compile(pattern, _re.IGNORECASE | _re.VERBOSE)


 class Template(metaclass=_TemplateMetaclass):
     """A string class for supporting $-substitutions."""

     delimiter = '$'
     idpattern = r'[_a-z][_a-z0-9]*'

     def __init__(self, template):
         self.template = template

     # Search for $$, $identifier, ${identifier}, and any bare $'s

     def _invalid(self, mo):
         i = mo.start('invalid')
         lines = self.template[:i].splitlines(True)
         if not lines:
             colno = 1
             lineno = 1
         else:
             colno = i - len(''.join(lines[:-1]))
             lineno = len(lines)
         raise ValueError('Invalid placeholder in string: line %d, col %d' %
                          (lineno, colno))

     def substitute(self, *args, **kws):
         if len(args) > 1:
             raise TypeError('Too many positional arguments')
         if not args:
             mapping = kws
         elif kws:
             mapping = _multimap(kws, args[0])
         else:
             mapping = args[0]
         # Helper function for .sub()
         def convert(mo):
             # Check the most common path first.
             named = mo.group('named') or mo.group('braced')
             if named is not None:
                 val = mapping[named]
                 # We use this idiom instead of str() because the latter will
                 # fail if val is a Unicode containing non-ASCII characters.
                 return '%s' % (val,)
             if mo.group('escaped') is not None:
                 return self.delimiter
             if mo.group('invalid') is not None:
                 self._invalid(mo)
             raise ValueError('Unrecognized named group in pattern',
                              self.pattern)
         return self.pattern.sub(convert, self.template)

     def safe_substitute(self, *args, **kws):
         if len(args) > 1:
             raise TypeError('Too many positional arguments')
         if not args:
             mapping = kws
         elif kws:
             mapping = _multimap(kws, args[0])
         else:
             mapping = args[0]
         # Helper function for .sub()
         def convert(mo):
             named = mo.group('named')
             if named is not None:
                 try:
                     # We use this idiom instead of str() because the latter
                     # will fail if val is a Unicode containing non-ASCII
                     return '%s' % (mapping[named],)
                 except KeyError:
                     return self.delimiter + named
             braced = mo.group('braced')
             if braced is not None:
                 try:
                     return '%s' % (mapping[braced],)
                 except KeyError:
                     return self.delimiter + '{' + braced + '}'
             if mo.group('escaped') is not None:
                 return self.delimiter
             if mo.group('invalid') is not None:
                 return self.delimiter
             raise ValueError('Unrecognized named group in pattern',
                              self.pattern)
         return self.pattern.sub(convert, self.template)


 ########################################################################
 # the Formatter class
 # see PEP 3101 for details and purpose of this class

 # The hard parts are reused from the C implementation.  They're exposed as "_"
 # prefixed methods of str and unicode.

 # The overall parser is implemented in str._formatter_parser.
 # The field name parser is implemented in str._formatter_field_name_split

 class Formatter:
     def format(self, format_string, *args, **kwargs):
         return self.vformat(format_string, args, kwargs)

     def vformat(self, format_string, args, kwargs):
         used_args = set()
         result = self._vformat(format_string, args, kwargs, used_args, 2)
         self.check_unused_args(used_args, args, kwargs)
         return result

     def _vformat(self, format_string, args, kwargs, used_args, recursion_depth):
         if recursion_depth < 0:
             raise ValueError('Max string recursion exceeded')
         result = []
         for literal_text, field_name, format_spec, conversion in \
                 self.parse(format_string):

             # output the literal text
             if literal_text:
                 result.append(literal_text)

             # if there's a field, output it
             if field_name is not None:
                 # this is some markup, find the object and do
                 #  the formatting

                 # given the field_name, find the object it references
                 #  and the argument it came from
                 obj, arg_used = self.get_field(field_name, args, kwargs)
                 used_args.add(arg_used)

                 # do any conversion on the resulting object
                 obj = self.convert_field(obj, conversion)

                 # expand the format spec, if needed
                 format_spec = self._vformat(format_spec, args, kwargs,
                                             used_args, recursion_depth-1)

                 # format the object and append to the result
                 result.append(self.format_field(obj, format_spec))

         return ''.join(result)


     def get_value(self, key, args, kwargs):
         if isinstance(key, int):
             return args[key]
         else:
             return kwargs[key]


     def check_unused_args(self, used_args, args, kwargs):
         pass


     def format_field(self, value, format_spec):
         return format(value, format_spec)


     def convert_field(self, value, conversion):
         # do any conversion on the resulting object
         if conversion == 'r':
             return repr(value)
         elif conversion == 's':
             return str(value)
         elif conversion is None:
             return value
         raise ValueError("Unknown converion specifier {0!s}".format(conversion))


     # returns an iterable that contains tuples of the form:
     # (literal_text, field_name, format_spec, conversion)
     # literal_text can be zero length
     # field_name can be None, in which case there's no
     #  object to format and output
     # if field_name is not None, it is looked up, formatted
     #  with format_spec and conversion and then used
     def parse(self, format_string):
         return format_string._formatter_parser()


     # given a field_name, find the object it references.
     #  field_name:   the field being looked up, e.g. "0.name"
     #                 or "lookup[3]"
     #  used_args:    a set of which args have been used
     #  args, kwargs: as passed in to vformat
     def get_field(self, field_name, args, kwargs):
         first, rest = field_name._formatter_field_name_split()

         obj = self.get_value(first, args, kwargs)

         # loop through the rest of the field_name, doing
         #  getattr or getitem as needed
         for is_attr, i in rest:
             if is_attr:
                 obj = getattr(obj, i)
             else:
                 obj = obj[i]

         return obj, first
	"""A collection of string constants.

	Public module variables:

	whitespace -- a string containing all ASCII whitespace
	ascii_lowercase -- a string containing all ASCII lowercase letters
	ascii_uppercase -- a string containing all ASCII uppercase letters
	ascii_letters -- a string containing all ASCII letters
	digits -- a string containing all ASCII decimal digits
	hexdigits -- a string containing all ASCII hexadecimal digits
	octdigits -- a string containing all ASCII octal digits
	punctuation -- a string containing all ASCII punctuation characters
	printable -- a string containing all ASCII characters considered printable

	"""

	# Some strings for ctype-style character classification
	whitespace = ' \t\n\r\v\f'
	ascii_lowercase = 'abcdefghijklmnopqrstuvwxyz'
	ascii_uppercase = 'ABCDEFGHIJKLMNOPQRSTUVWXYZ'
	ascii_letters = ascii_lowercase + ascii_uppercase
	digits = '0123456789'
	hexdigits = digits + 'abcdef' + 'ABCDEF'
	octdigits = '01234567'
	punctuation = """!"#$%&'()*+,-./:;<=>?@[\]^_`{\|}~"""
	printable = digits + ascii_letters + punctuation + whitespace

	# Functions which aren't available as string methods.

	# Capitalize the words in a string, e.g. " aBc dEf " -> "Abc Def".
	def capwords(s, sep=None):
	"""capwords(s, [sep]) -> string

	Split the argument into words using split, capitalize each
	word using capitalize, and join the capitalized words using
	join. Note that this replaces runs of whitespace characters by
	a single space.

	"""
	return (sep or ' ').join([x.capitalize() for x in s.split(sep)])


	####################################################################
	import re as _re

	class _multimap:
	"""Helper class for combining multiple mappings.

	Used by .{safe_,}substitute() to combine the mapping and keyword
	arguments.
	"""
	def __init__(self, primary, secondary):
	self._primary = primary
	self._secondary = secondary

	def __getitem__(self, key):
	try:
	return self._primary[key]
	except KeyError:
	return self._secondary[key]


	class _TemplateMetaclass(type):
	pattern = r"""
	%(delim)s(?:
	(?P<escaped>%(delim)s) \| # Escape sequence of two delimiters
	(?P<named>%(id)s) \| # delimiter and a Python identifier
	{(?P<braced>%(id)s)} \| # delimiter and a braced identifier
	(?P<invalid>) # Other ill-formed delimiter exprs
	)
	"""

	def __init__(cls, name, bases, dct):
	super(_TemplateMetaclass, cls).__init__(name, bases, dct)
	if 'pattern' in dct:
	pattern = cls.pattern
	else:
	pattern = _TemplateMetaclass.pattern % {
	'delim' : _re.escape(cls.delimiter),
	'id' : cls.idpattern,
	}
	cls.pattern = _re.compile(pattern, _re.IGNORECASE \| _re.VERBOSE)


	class Template(metaclass=_TemplateMetaclass):
	"""A string class for supporting $-substitutions."""

	delimiter = '$'
	idpattern = r'[_a-z][_a-z0-9]*'

	def __init__(self, template):
	self.template = template

	# Search for $$, $identifier, ${identifier}, and any bare $'s

	def _invalid(self, mo):
	i = mo.start('invalid')
	lines = self.template[:i].splitlines(True)
	if not lines:
	colno = 1
	lineno = 1
	else:
	colno = i - len(''.join(lines[:-1]))
	lineno = len(lines)
	raise ValueError('Invalid placeholder in string: line %d, col %d' %
	(lineno, colno))

	def substitute(self, args, *kws):
	if len(args) > 1:
	raise TypeError('Too many positional arguments')
	if not args:
	mapping = kws
	elif kws:
	mapping = _multimap(kws, args[0])
	else:
	mapping = args[0]
	# Helper function for .sub()
	def convert(mo):
	# Check the most common path first.
	named = mo.group('named') or mo.group('braced')
	if named is not None:
	val = mapping[named]
	# We use this idiom instead of str() because the latter will
	# fail if val is a Unicode containing non-ASCII characters.
	return '%s' % (val,)
	if mo.group('escaped') is not None:
	return self.delimiter
	if mo.group('invalid') is not None:
	self._invalid(mo)
	raise ValueError('Unrecognized named group in pattern',
	self.pattern)
	return self.pattern.sub(convert, self.template)

	def safe_substitute(self, args, *kws):
	if len(args) > 1:
	raise TypeError('Too many positional arguments')
	if not args:
	mapping = kws
	elif kws:
	mapping = _multimap(kws, args[0])
	else:
	mapping = args[0]
	# Helper function for .sub()
	def convert(mo):
	named = mo.group('named')
	if named is not None:
	try:
	# We use this idiom instead of str() because the latter
	# will fail if val is a Unicode containing non-ASCII
	return '%s' % (mapping[named],)
	except KeyError:
	return self.delimiter + named
	braced = mo.group('braced')
	if braced is not None:
	try:
	return '%s' % (mapping[braced],)
	except KeyError:
	return self.delimiter + '{' + braced + '}'
	if mo.group('escaped') is not None:
	return self.delimiter
	if mo.group('invalid') is not None:
	return self.delimiter
	raise ValueError('Unrecognized named group in pattern',
	self.pattern)
	return self.pattern.sub(convert, self.template)



	########################################################################
	# the Formatter class
	# see PEP 3101 for details and purpose of this class

	# The hard parts are reused from the C implementation. They're exposed as "_"
	# prefixed methods of str and unicode.

	# The overall parser is implemented in str._formatter_parser.
	# The field name parser is implemented in str._formatter_field_name_split

	class Formatter:
	def format(self, format_string, args, *kwargs):
	return self.vformat(format_string, args, kwargs)

	def vformat(self, format_string, args, kwargs):
	used_args = set()
	result = self._vformat(format_string, args, kwargs, used_args, 2)
	self.check_unused_args(used_args, args, kwargs)
	return result

	def _vformat(self, format_string, args, kwargs, used_args, recursion_depth):
	if recursion_depth < 0:
	raise ValueError('Max string recursion exceeded')
	result = []
	for literal_text, field_name, format_spec, conversion in \
	self.parse(format_string):

	# output the literal text
	if literal_text:
	result.append(literal_text)

	# if there's a field, output it
	if field_name is not None:
	# this is some markup, find the object and do
	# the formatting

	# given the field_name, find the object it references
	# and the argument it came from
	obj, arg_used = self.get_field(field_name, args, kwargs)
	used_args.add(arg_used)

	# do any conversion on the resulting object
	obj = self.convert_field(obj, conversion)

	# expand the format spec, if needed
	format_spec = self._vformat(format_spec, args, kwargs,
	used_args, recursion_depth-1)

	# format the object and append to the result
	result.append(self.format_field(obj, format_spec))

	return ''.join(result)


	def get_value(self, key, args, kwargs):
	if isinstance(key, int):
	return args[key]
	else:
	return kwargs[key]


	def check_unused_args(self, used_args, args, kwargs):
	pass


	def format_field(self, value, format_spec):
	return format(value, format_spec)


	def convert_field(self, value, conversion):
	# do any conversion on the resulting object
	if conversion == 'r':
	return repr(value)
	elif conversion == 's':
	return str(value)
	elif conversion is None:
	return value
	raise ValueError("Unknown converion specifier {0!s}".format(conversion))


	# returns an iterable that contains tuples of the form:
	# (literal_text, field_name, format_spec, conversion)
	# literal_text can be zero length
	# field_name can be None, in which case there's no
	# object to format and output
	# if field_name is not None, it is looked up, formatted
	# with format_spec and conversion and then used
	def parse(self, format_string):
	return format_string._formatter_parser()


	# given a field_name, find the object it references.
	# field_name: the field being looked up, e.g. "0.name"
	# or "lookup[3]"
	# used_args: a set of which args have been used
	# args, kwargs: as passed in to vformat
	def get_field(self, field_name, args, kwargs):
	first, rest = field_name._formatter_field_name_split()

	obj = self.get_value(first, args, kwargs)

	# loop through the rest of the field_name, doing
	# getattr or getitem as needed
	for is_attr, i in rest:
	if is_attr:
	obj = getattr(obj, i)
	else:
	obj = obj[i]

	return obj, first