"""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. If the optional second argument sep is absent or None, runs of whitespace characters are replaced by a single space and leading and trailing whitespace are removed, otherwise sep is used to split and join the words. """ 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%(delim)s) | # Escape sequence of two delimiters (?P%(id)s) | # delimiter and a Python identifier {(?P%(id)s)} | # delimiter and a braced identifier (?P) # 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, cls.flags | _re.VERBOSE) class Template(metaclass=_TemplateMetaclass): """A string class for supporting $-substitutions.""" delimiter = '$' idpattern = r'[_a-z][_a-z0-9]*' flags = _re.IGNORECASE 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. # 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 conversion 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