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# Licensed under the LGPL: https://www.gnu.org/licenses/old-licenses/lgpl-2.1.en.html # For details: https://github.com/PyCQA/astroid/blob/main/LICENSE # Copyright (c) https://github.com/PyCQA/astroid/blob/main/CONTRIBUTORS.txt """Classes representing different types of constraints on inference values.""" from __future__ import annotations import sys from abc import ABC, abstractmethod from collections.abc import Iterator from typing import Union from astroid import bases, nodes, util from astroid.typing import InferenceResult if sys.version_info >= (3, 11): from typing import Self else: from typing_extensions import Self _NameNodes = Union[nodes.AssignAttr, nodes.Attribute, nodes.AssignName, nodes.Name] class Constraint(ABC): """Represents a single constraint on a variable.""" def __init__(self, node: nodes.NodeNG, negate: bool) -> None: self.node = node """The node that this constraint applies to.""" self.negate = negate """True if this constraint is negated. E.g., "is not" instead of "is".""" @classmethod @abstractmethod def match( cls: type[Self], node: _NameNodes, expr: nodes.NodeNG, negate: bool = False ) -> Self | None: """Return a new constraint for node matched from expr, if expr matches the constraint pattern. If negate is True, negate the constraint. """ @abstractmethod def satisfied_by(self, inferred: InferenceResult) -> bool: """Return True if this constraint is satisfied by the given inferred value.""" class NoneConstraint(Constraint): """Represents an "is None" or "is not None" constraint.""" CONST_NONE: nodes.Const = nodes.Const(None) @classmethod def match( cls: type[Self], node: _NameNodes, expr: nodes.NodeNG, negate: bool = False ) -> Self | None: """Return a new constraint for node matched from expr, if expr matches the constraint pattern. Negate the constraint based on the value of negate. """ if isinstance(expr, nodes.Compare) and len(expr.ops) == 1: left = expr.left op, right = expr.ops[0] if op in {"is", "is not"} and ( _matches(left, node) and _matches(right, cls.CONST_NONE) ): negate = (op == "is" and negate) or (op == "is not" and not negate) return cls(node=node, negate=negate) return None def satisfied_by(self, inferred: InferenceResult) -> bool: """Return True if this constraint is satisfied by the given inferred value.""" # Assume true if uninferable if isinstance(inferred, util.UninferableBase): return True # Return the XOR of self.negate and matches(inferred, self.CONST_NONE) return self.negate ^ _matches(inferred, self.CONST_NONE) def get_constraints( expr: _NameNodes, frame: nodes.LocalsDictNodeNG ) -> dict[nodes.If, set[Constraint]]: """Returns the constraints for the given expression. The returned dictionary maps the node where the constraint was generated to the corresponding constraint(s). Constraints are computed statically by analysing the code surrounding expr. Currently this only supports constraints generated from if conditions. """ current_node: nodes.NodeNG | None = expr constraints_mapping: dict[nodes.If, set[Constraint]] = {} while current_node is not None and current_node is not frame: parent = current_node.parent if isinstance(parent, nodes.If): branch, _ = parent.locate_child(current_node) constraints: set[Constraint] | None = None if branch == "body": constraints = set(_match_constraint(expr, parent.test)) elif branch == "orelse": constraints = set(_match_constraint(expr, parent.test, invert=True)) if constraints: constraints_mapping[parent] = constraints current_node = parent return constraints_mapping ALL_CONSTRAINT_CLASSES = frozenset((NoneConstraint,)) """All supported constraint types.""" def _matches(node1: nodes.NodeNG | bases.Proxy, node2: nodes.NodeNG) -> bool: """Returns True if the two nodes match.""" if isinstance(node1, nodes.Name) and isinstance(node2, nodes.Name): return node1.name == node2.name if isinstance(node1, nodes.Attribute) and isinstance(node2, nodes.Attribute): return node1.attrname == node2.attrname and _matches(node1.expr, node2.expr) if isinstance(node1, nodes.Const) and isinstance(node2, nodes.Const): return node1.value == node2.value return False def _match_constraint( node: _NameNodes, expr: nodes.NodeNG, invert: bool = False ) -> Iterator[Constraint]: """Yields all constraint patterns for node that match.""" for constraint_cls in ALL_CONSTRAINT_CLASSES: constraint = constraint_cls.match(node, expr, invert) if constraint: yield constraint