There's also a pattern matching implementation here.
"""
-# mypy: allow-untyped-defs
+# mypy: allow-untyped-defs, allow-incomplete-defs
from typing import (
Any,
- Callable,
Dict,
Iterator,
List,
return NotImplemented
return self._eq(other)
- __hash__ = None # type: Any # For Py3 compatibility.
-
@property
def prefix(self) -> Text:
raise NotImplementedError
"""
return "".join(map(str, self.children))
- def _eq(self, other) -> bool:
+ def _eq(self, other: Base) -> bool:
"""Compare two nodes for equality."""
return (self.type, self.children) == (other.type, other.children)
return self.children[0].prefix
@prefix.setter
- def prefix(self, prefix) -> None:
+ def prefix(self, prefix: Text) -> None:
if self.children:
self.children[0].prefix = prefix
value: Text
fixers_applied: List[Any]
bracket_depth: int
- opening_bracket: "Leaf"
+ # Changed later in brackets.py
+ opening_bracket: Optional["Leaf"] = None
used_names: Optional[Set[Text]]
_prefix = "" # Whitespace and comments preceding this token in the input
lineno: int = 0 # Line where this token starts in the input
column: int = 0 # Column where this token starts in the input
+ # If not None, this Leaf is created by converting a block of fmt off/skip
+ # code, and `fmt_pass_converted_first_leaf` points to the first Leaf in the
+ # converted code.
+ fmt_pass_converted_first_leaf: Optional["Leaf"] = None
def __init__(
self,
context: Optional[Context] = None,
prefix: Optional[Text] = None,
fixers_applied: List[Any] = [],
+ opening_bracket: Optional["Leaf"] = None,
+ fmt_pass_converted_first_leaf: Optional["Leaf"] = None,
) -> None:
"""
Initializer.
self._prefix = prefix
self.fixers_applied: Optional[List[Any]] = fixers_applied[:]
self.children = []
+ self.opening_bracket = opening_bracket
+ self.fmt_pass_converted_first_leaf = fmt_pass_converted_first_leaf
def __repr__(self) -> str:
"""Return a canonical string representation."""
This reproduces the input source exactly.
"""
- return self.prefix + str(self.value)
+ return self._prefix + str(self.value)
- def _eq(self, other) -> bool:
+ def _eq(self, other: "Leaf") -> bool:
"""Compare two nodes for equality."""
return (self.type, self.value) == (other.type, other.value)
return self._prefix
@prefix.setter
- def prefix(self, prefix) -> None:
+ def prefix(self, prefix: Text) -> None:
self.changed()
self._prefix = prefix
self.content = content
self.name = name
- def match(self, node: NL, results=None):
+ def match(self, node: NL, results=None) -> bool:
"""Override match() to insist on a leaf node."""
if not isinstance(node, Leaf):
return False
newcontent = list(content)
for i, item in enumerate(newcontent):
assert isinstance(item, BasePattern), (i, item)
- if isinstance(item, WildcardPattern):
- self.wildcards = True
+ # I don't even think this code is used anywhere, but it does cause
+ # unreachable errors from mypy. This function's signature does look
+ # odd though *shrug*.
+ if isinstance(item, WildcardPattern): # type: ignore[unreachable]
+ self.wildcards = True # type: ignore[unreachable]
self.type = type
- self.content = newcontent
+ self.content = newcontent # TODO: this is unbound when content is None
self.name = name
def _submatch(self, node, results=None) -> bool:
class NegatedPattern(BasePattern):
- def __init__(self, content: Optional[Any] = None) -> None:
+ def __init__(self, content: Optional[BasePattern] = None) -> None:
"""
Initializer.
# We only match an empty sequence of nodes in its entirety
return len(nodes) == 0
- def generate_matches(self, nodes) -> Iterator[Tuple[int, _Results]]:
+ def generate_matches(self, nodes: List[NL]) -> Iterator[Tuple[int, _Results]]:
if self.content is None:
# Return a match if there is an empty sequence
if len(nodes) == 0:
r.update(r0)
r.update(r1)
yield c0 + c1, r
-
-
-_Convert = Callable[[Grammar, RawNode], Any]