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- ## Lexer Implementation
-
- import re
-
- from .utils import Str, classify, get_regexp_width, Py36
- from .exceptions import UnexpectedCharacters, LexError
-
- class Pattern(object):
- def __init__(self, value, flags=()):
- self.value = value
- self.flags = frozenset(flags)
-
- def __repr__(self):
- return repr(self.to_regexp())
-
- # Pattern Hashing assumes all subclasses have a different priority!
- def __hash__(self):
- return hash((type(self), self.value, self.flags))
- def __eq__(self, other):
- return type(self) == type(other) and self.value == other.value and self.flags == other.flags
-
- def to_regexp(self):
- raise NotImplementedError()
-
- if Py36:
- # Python 3.6 changed syntax for flags in regular expression
- def _get_flags(self, value):
- for f in self.flags:
- value = ('(?%s:%s)' % (f, value))
- return value
-
- else:
- def _get_flags(self, value):
- for f in self.flags:
- value = ('(?%s)' % f) + value
- return value
-
- class PatternStr(Pattern):
- def to_regexp(self):
- return self._get_flags(re.escape(self.value))
-
- @property
- def min_width(self):
- return len(self.value)
- max_width = min_width
-
- class PatternRE(Pattern):
- def to_regexp(self):
- return self._get_flags(self.value)
-
- @property
- def min_width(self):
- return get_regexp_width(self.to_regexp())[0]
- @property
- def max_width(self):
- return get_regexp_width(self.to_regexp())[1]
-
- class TerminalDef(object):
- def __init__(self, name, pattern, priority=1):
- assert isinstance(pattern, Pattern), pattern
- self.name = name
- self.pattern = pattern
- self.priority = priority
-
- def __repr__(self):
- return '%s(%r, %r)' % (type(self).__name__, self.name, self.pattern)
-
-
-
- ###{standalone
- class Token(Str):
- __slots__ = ('type', 'pos_in_stream', 'value', 'line', 'column', 'end_line', 'end_column')
-
- def __new__(cls, type_, value, pos_in_stream=None, line=None, column=None, end_line=None, end_column=None):
- try:
- self = super(Token, cls).__new__(cls, value)
- except UnicodeDecodeError:
- value = value.decode('latin1')
- self = super(Token, cls).__new__(cls, value)
-
- self.type = type_
- self.pos_in_stream = pos_in_stream
- self.value = value
- self.line = line
- self.column = column
- self.end_line = end_line
- self.end_column = end_column
- return self
-
- @classmethod
- def new_borrow_pos(cls, type_, value, borrow_t):
- return cls(type_, value, borrow_t.pos_in_stream, borrow_t.line, borrow_t.column, borrow_t.end_line, borrow_t.end_column)
-
- def __reduce__(self):
- return (self.__class__, (self.type, self.value, self.pos_in_stream, self.line, self.column, ))
-
- def __repr__(self):
- return 'Token(%s, %r)' % (self.type, self.value)
-
- def __deepcopy__(self, memo):
- return Token(self.type, self.value, self.pos_in_stream, self.line, self.column)
-
- def __eq__(self, other):
- if isinstance(other, Token) and self.type != other.type:
- return False
-
- return Str.__eq__(self, other)
-
- __hash__ = Str.__hash__
-
-
- class LineCounter:
- def __init__(self):
- self.newline_char = '\n'
- self.char_pos = 0
- self.line = 1
- self.column = 1
- self.line_start_pos = 0
-
- def feed(self, token, test_newline=True):
- """Consume a token and calculate the new line & column.
-
- As an optional optimization, set test_newline=False is token doesn't contain a newline.
- """
- if test_newline:
- newlines = token.count(self.newline_char)
- if newlines:
- self.line += newlines
- self.line_start_pos = self.char_pos + token.rindex(self.newline_char) + 1
-
- self.char_pos += len(token)
- self.column = self.char_pos - self.line_start_pos + 1
-
- class _Lex:
- "Built to serve both Lexer and ContextualLexer"
- def __init__(self, lexer, state=None):
- self.lexer = lexer
- self.state = state
-
- def lex(self, stream, newline_types, ignore_types):
- newline_types = frozenset(newline_types)
- ignore_types = frozenset(ignore_types)
- line_ctr = LineCounter()
-
- while line_ctr.char_pos < len(stream):
- lexer = self.lexer
- for mre, type_from_index in lexer.mres:
- m = mre.match(stream, line_ctr.char_pos)
- if not m:
- continue
-
- t = None
- value = m.group(0)
- type_ = type_from_index[m.lastindex]
- if type_ not in ignore_types:
- t = Token(type_, value, line_ctr.char_pos, line_ctr.line, line_ctr.column)
- if t.type in lexer.callback:
- t = lexer.callback[t.type](t)
- if not isinstance(t, Token):
- raise ValueError("Callbacks must return a token (returned %r)" % t)
- yield t
- else:
- if type_ in lexer.callback:
- t = Token(type_, value, line_ctr.char_pos, line_ctr.line, line_ctr.column)
- lexer.callback[type_](t)
-
- line_ctr.feed(value, type_ in newline_types)
- if t:
- t.end_line = line_ctr.line
- t.end_column = line_ctr.column
-
- break
- else:
- allowed = [v for m, tfi in lexer.mres for v in tfi.values()]
- raise UnexpectedCharacters(stream, line_ctr.char_pos, line_ctr.line, line_ctr.column, allowed=allowed, state=self.state)
-
-
- class UnlessCallback:
- def __init__(self, mres):
- self.mres = mres
-
- def __call__(self, t):
- for mre, type_from_index in self.mres:
- m = mre.match(t.value)
- if m:
- t.type = type_from_index[m.lastindex]
- break
- return t
-
- class CallChain:
- def __init__(self, callback1, callback2, cond):
- self.callback1 = callback1
- self.callback2 = callback2
- self.cond = cond
-
- def __call__(self, t):
- t2 = self.callback1(t)
- return self.callback2(t) if self.cond(t2) else t2
-
-
- ###}
-
-
-
- def _create_unless(terminals):
- tokens_by_type = classify(terminals, lambda t: type(t.pattern))
- assert len(tokens_by_type) <= 2, tokens_by_type.keys()
- embedded_strs = set()
- callback = {}
- for retok in tokens_by_type.get(PatternRE, []):
- unless = [] # {}
- for strtok in tokens_by_type.get(PatternStr, []):
- if strtok.priority > retok.priority:
- continue
- s = strtok.pattern.value
- m = re.match(retok.pattern.to_regexp(), s)
- if m and m.group(0) == s:
- unless.append(strtok)
- if strtok.pattern.flags <= retok.pattern.flags:
- embedded_strs.add(strtok)
- if unless:
- callback[retok.name] = UnlessCallback(build_mres(unless, match_whole=True))
-
- terminals = [t for t in terminals if t not in embedded_strs]
- return terminals, callback
-
-
- def _build_mres(terminals, max_size, match_whole):
- # Python sets an unreasonable group limit (currently 100) in its re module
- # Worse, the only way to know we reached it is by catching an AssertionError!
- # This function recursively tries less and less groups until it's successful.
- postfix = '$' if match_whole else ''
- mres = []
- while terminals:
- try:
- mre = re.compile(u'|'.join(u'(?P<%s>%s)'%(t.name, t.pattern.to_regexp()+postfix) for t in terminals[:max_size]))
- except AssertionError: # Yes, this is what Python provides us.. :/
- return _build_mres(terminals, max_size//2, match_whole)
-
- # terms_from_name = {t.name: t for t in terminals[:max_size]}
- mres.append((mre, {i:n for n,i in mre.groupindex.items()} ))
- terminals = terminals[max_size:]
- return mres
-
- def build_mres(terminals, match_whole=False):
- return _build_mres(terminals, len(terminals), match_whole)
-
- def _regexp_has_newline(r):
- """Expressions that may indicate newlines in a regexp:
- - newlines (\n)
- - escaped newline (\\n)
- - anything but ([^...])
- - any-char (.) when the flag (?s) exists
- """
- return '\n' in r or '\\n' in r or '[^' in r or ('(?s' in r and '.' in r)
-
- class Lexer:
- """Lexer interface
-
- Method Signatures:
- lex(self, stream) -> Iterator[Token]
-
- set_parser_state(self, state) # Optional
- """
- set_parser_state = NotImplemented
- lex = NotImplemented
-
- class TraditionalLexer(Lexer):
- def __init__(self, terminals, ignore=(), user_callbacks={}):
- assert all(isinstance(t, TerminalDef) for t in terminals), terminals
-
- terminals = list(terminals)
-
- # Sanitization
- for t in terminals:
- try:
- re.compile(t.pattern.to_regexp())
- except:
- raise LexError("Cannot compile token %s: %s" % (t.name, t.pattern))
-
- if t.pattern.min_width == 0:
- raise LexError("Lexer does not allow zero-width terminals. (%s: %s)" % (t.name, t.pattern))
-
- assert set(ignore) <= {t.name for t in terminals}
-
- # Init
- self.newline_types = [t.name for t in terminals if _regexp_has_newline(t.pattern.to_regexp())]
- self.ignore_types = list(ignore)
-
- terminals.sort(key=lambda x:(-x.priority, -x.pattern.max_width, -len(x.pattern.value), x.name))
-
- terminals, self.callback = _create_unless(terminals)
- assert all(self.callback.values())
-
- for type_, f in user_callbacks.items():
- if type_ in self.callback:
- # Already a callback there, probably UnlessCallback
- self.callback[type_] = CallChain(self.callback[type_], f, lambda t: t.type == type_)
- else:
- self.callback[type_] = f
-
- self.terminals = terminals
-
- self.mres = build_mres(terminals)
-
-
- def lex(self, stream):
- return _Lex(self).lex(stream, self.newline_types, self.ignore_types)
-
-
- class ContextualLexer(Lexer):
- def __init__(self, terminals, states, ignore=(), always_accept=(), user_callbacks={}):
- tokens_by_name = {}
- for t in terminals:
- assert t.name not in tokens_by_name, t
- tokens_by_name[t.name] = t
-
- lexer_by_tokens = {}
- self.lexers = {}
- for state, accepts in states.items():
- key = frozenset(accepts)
- try:
- lexer = lexer_by_tokens[key]
- except KeyError:
- accepts = set(accepts) | set(ignore) | set(always_accept)
- state_tokens = [tokens_by_name[n] for n in accepts if n and n in tokens_by_name]
- lexer = TraditionalLexer(state_tokens, ignore=ignore, user_callbacks=user_callbacks)
- lexer_by_tokens[key] = lexer
-
- self.lexers[state] = lexer
-
- self.root_lexer = TraditionalLexer(terminals, ignore=ignore, user_callbacks=user_callbacks)
-
- self.set_parser_state(None) # Needs to be set on the outside
-
- def set_parser_state(self, state):
- self.parser_state = state
-
- def lex(self, stream):
- l = _Lex(self.lexers[self.parser_state], self.parser_state)
- for x in l.lex(stream, self.root_lexer.newline_types, self.root_lexer.ignore_types):
- yield x
- l.lexer = self.lexers[self.parser_state]
- l.state = self.parser_state
-
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