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validate that ESC_PAREN ('/') is followed by a callable name and not empty
validate that ESC_PAREN ('/') is followed by a callable name and not empty

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guarded_eval.py
898 lines | 28.8 KiB | text/x-python | PythonLexer
from inspect import isclass, signature, Signature
from typing import (
Annotated,
AnyStr,
Callable,
Dict,
Literal,
NamedTuple,
NewType,
Optional,
Protocol,
Set,
Sequence,
Tuple,
Type,
TypeGuard,
Union,
get_args,
get_origin,
is_typeddict,
)
import ast
import builtins
import collections
import operator
import sys
from functools import cached_property
from dataclasses import dataclass, field
from types import MethodDescriptorType, ModuleType
from IPython.utils.decorators import undoc
if sys.version_info < (3, 11):
from typing_extensions import Self, LiteralString
else:
from typing import Self, LiteralString
if sys.version_info < (3, 12):
from typing_extensions import TypeAliasType
else:
from typing import TypeAliasType
@undoc
class HasGetItem(Protocol):
def __getitem__(self, key) -> None:
...
@undoc
class InstancesHaveGetItem(Protocol):
def __call__(self, *args, **kwargs) -> HasGetItem:
...
@undoc
class HasGetAttr(Protocol):
def __getattr__(self, key) -> None:
...
@undoc
class DoesNotHaveGetAttr(Protocol):
pass
# By default `__getattr__` is not explicitly implemented on most objects
MayHaveGetattr = Union[HasGetAttr, DoesNotHaveGetAttr]
def _unbind_method(func: Callable) -> Union[Callable, None]:
"""Get unbound method for given bound method.
Returns None if cannot get unbound method, or method is already unbound.
"""
owner = getattr(func, "__self__", None)
owner_class = type(owner)
name = getattr(func, "__name__", None)
instance_dict_overrides = getattr(owner, "__dict__", None)
if (
owner is not None
and name
and (
not instance_dict_overrides
or (instance_dict_overrides and name not in instance_dict_overrides)
)
):
return getattr(owner_class, name)
return None
@undoc
@dataclass
class EvaluationPolicy:
"""Definition of evaluation policy."""
allow_locals_access: bool = False
allow_globals_access: bool = False
allow_item_access: bool = False
allow_attr_access: bool = False
allow_builtins_access: bool = False
allow_all_operations: bool = False
allow_any_calls: bool = False
allowed_calls: Set[Callable] = field(default_factory=set)
def can_get_item(self, value, item):
return self.allow_item_access
def can_get_attr(self, value, attr):
return self.allow_attr_access
def can_operate(self, dunders: Tuple[str, ...], a, b=None):
if self.allow_all_operations:
return True
def can_call(self, func):
if self.allow_any_calls:
return True
if func in self.allowed_calls:
return True
owner_method = _unbind_method(func)
if owner_method and owner_method in self.allowed_calls:
return True
def _get_external(module_name: str, access_path: Sequence[str]):
"""Get value from external module given a dotted access path.
Raises:
* `KeyError` if module is removed not found, and
* `AttributeError` if access path does not match an exported object
"""
member_type = sys.modules[module_name]
for attr in access_path:
member_type = getattr(member_type, attr)
return member_type
def _has_original_dunder_external(
value,
module_name: str,
access_path: Sequence[str],
method_name: str,
):
if module_name not in sys.modules:
# LBYLB as it is faster
return False
try:
member_type = _get_external(module_name, access_path)
value_type = type(value)
if type(value) == member_type:
return True
if method_name == "__getattribute__":
# we have to short-circuit here due to an unresolved issue in
# `isinstance` implementation: https://bugs.python.org/issue32683
return False
if isinstance(value, member_type):
method = getattr(value_type, method_name, None)
member_method = getattr(member_type, method_name, None)
if member_method == method:
return True
except (AttributeError, KeyError):
return False
def _has_original_dunder(
value, allowed_types, allowed_methods, allowed_external, method_name
):
# note: Python ignores `__getattr__`/`__getitem__` on instances,
# we only need to check at class level
value_type = type(value)
# strict type check passes → no need to check method
if value_type in allowed_types:
return True
method = getattr(value_type, method_name, None)
if method is None:
return None
if method in allowed_methods:
return True
for module_name, *access_path in allowed_external:
if _has_original_dunder_external(value, module_name, access_path, method_name):
return True
return False
@undoc
@dataclass
class SelectivePolicy(EvaluationPolicy):
allowed_getitem: Set[InstancesHaveGetItem] = field(default_factory=set)
allowed_getitem_external: Set[Tuple[str, ...]] = field(default_factory=set)
allowed_getattr: Set[MayHaveGetattr] = field(default_factory=set)
allowed_getattr_external: Set[Tuple[str, ...]] = field(default_factory=set)
allowed_operations: Set = field(default_factory=set)
allowed_operations_external: Set[Tuple[str, ...]] = field(default_factory=set)
_operation_methods_cache: Dict[str, Set[Callable]] = field(
default_factory=dict, init=False
)
def can_get_attr(self, value, attr):
has_original_attribute = _has_original_dunder(
value,
allowed_types=self.allowed_getattr,
allowed_methods=self._getattribute_methods,
allowed_external=self.allowed_getattr_external,
method_name="__getattribute__",
)
has_original_attr = _has_original_dunder(
value,
allowed_types=self.allowed_getattr,
allowed_methods=self._getattr_methods,
allowed_external=self.allowed_getattr_external,
method_name="__getattr__",
)
accept = False
# Many objects do not have `__getattr__`, this is fine.
if has_original_attr is None and has_original_attribute:
accept = True
else:
# Accept objects without modifications to `__getattr__` and `__getattribute__`
accept = has_original_attr and has_original_attribute
if accept:
# We still need to check for overridden properties.
value_class = type(value)
if not hasattr(value_class, attr):
return True
class_attr_val = getattr(value_class, attr)
is_property = isinstance(class_attr_val, property)
if not is_property:
return True
# Properties in allowed types are ok (although we do not include any
# properties in our default allow list currently).
if type(value) in self.allowed_getattr:
return True # pragma: no cover
# Properties in subclasses of allowed types may be ok if not changed
for module_name, *access_path in self.allowed_getattr_external:
try:
external_class = _get_external(module_name, access_path)
external_class_attr_val = getattr(external_class, attr)
except (KeyError, AttributeError):
return False # pragma: no cover
return class_attr_val == external_class_attr_val
return False
def can_get_item(self, value, item):
"""Allow accessing `__getiitem__` of allow-listed instances unless it was not modified."""
return _has_original_dunder(
value,
allowed_types=self.allowed_getitem,
allowed_methods=self._getitem_methods,
allowed_external=self.allowed_getitem_external,
method_name="__getitem__",
)
def can_operate(self, dunders: Tuple[str, ...], a, b=None):
objects = [a]
if b is not None:
objects.append(b)
return all(
[
_has_original_dunder(
obj,
allowed_types=self.allowed_operations,
allowed_methods=self._operator_dunder_methods(dunder),
allowed_external=self.allowed_operations_external,
method_name=dunder,
)
for dunder in dunders
for obj in objects
]
)
def _operator_dunder_methods(self, dunder: str) -> Set[Callable]:
if dunder not in self._operation_methods_cache:
self._operation_methods_cache[dunder] = self._safe_get_methods(
self.allowed_operations, dunder
)
return self._operation_methods_cache[dunder]
@cached_property
def _getitem_methods(self) -> Set[Callable]:
return self._safe_get_methods(self.allowed_getitem, "__getitem__")
@cached_property
def _getattr_methods(self) -> Set[Callable]:
return self._safe_get_methods(self.allowed_getattr, "__getattr__")
@cached_property
def _getattribute_methods(self) -> Set[Callable]:
return self._safe_get_methods(self.allowed_getattr, "__getattribute__")
def _safe_get_methods(self, classes, name) -> Set[Callable]:
return {
method
for class_ in classes
for method in [getattr(class_, name, None)]
if method
}
class _DummyNamedTuple(NamedTuple):
"""Used internally to retrieve methods of named tuple instance."""
class EvaluationContext(NamedTuple):
#: Local namespace
locals: dict
#: Global namespace
globals: dict
#: Evaluation policy identifier
evaluation: Literal[
"forbidden", "minimal", "limited", "unsafe", "dangerous"
] = "forbidden"
#: Whether the evaluation of code takes place inside of a subscript.
#: Useful for evaluating ``:-1, 'col'`` in ``df[:-1, 'col']``.
in_subscript: bool = False
class _IdentitySubscript:
"""Returns the key itself when item is requested via subscript."""
def __getitem__(self, key):
return key
IDENTITY_SUBSCRIPT = _IdentitySubscript()
SUBSCRIPT_MARKER = "__SUBSCRIPT_SENTINEL__"
UNKNOWN_SIGNATURE = Signature()
NOT_EVALUATED = object()
class GuardRejection(Exception):
"""Exception raised when guard rejects evaluation attempt."""
pass
def guarded_eval(code: str, context: EvaluationContext):
"""Evaluate provided code in the evaluation context.
If evaluation policy given by context is set to ``forbidden``
no evaluation will be performed; if it is set to ``dangerous``
standard :func:`eval` will be used; finally, for any other,
policy :func:`eval_node` will be called on parsed AST.
"""
locals_ = context.locals
if context.evaluation == "forbidden":
raise GuardRejection("Forbidden mode")
# note: not using `ast.literal_eval` as it does not implement
# getitem at all, for example it fails on simple `[0][1]`
if context.in_subscript:
# syntactic sugar for ellipsis (:) is only available in subscripts
# so we need to trick the ast parser into thinking that we have
# a subscript, but we need to be able to later recognise that we did
# it so we can ignore the actual __getitem__ operation
if not code:
return tuple()
locals_ = locals_.copy()
locals_[SUBSCRIPT_MARKER] = IDENTITY_SUBSCRIPT
code = SUBSCRIPT_MARKER + "[" + code + "]"
context = EvaluationContext(**{**context._asdict(), **{"locals": locals_}})
if context.evaluation == "dangerous":
return eval(code, context.globals, context.locals)
expression = ast.parse(code, mode="eval")
return eval_node(expression, context)
BINARY_OP_DUNDERS: Dict[Type[ast.operator], Tuple[str]] = {
ast.Add: ("__add__",),
ast.Sub: ("__sub__",),
ast.Mult: ("__mul__",),
ast.Div: ("__truediv__",),
ast.FloorDiv: ("__floordiv__",),
ast.Mod: ("__mod__",),
ast.Pow: ("__pow__",),
ast.LShift: ("__lshift__",),
ast.RShift: ("__rshift__",),
ast.BitOr: ("__or__",),
ast.BitXor: ("__xor__",),
ast.BitAnd: ("__and__",),
ast.MatMult: ("__matmul__",),
}
COMP_OP_DUNDERS: Dict[Type[ast.cmpop], Tuple[str, ...]] = {
ast.Eq: ("__eq__",),
ast.NotEq: ("__ne__", "__eq__"),
ast.Lt: ("__lt__", "__gt__"),
ast.LtE: ("__le__", "__ge__"),
ast.Gt: ("__gt__", "__lt__"),
ast.GtE: ("__ge__", "__le__"),
ast.In: ("__contains__",),
# Note: ast.Is, ast.IsNot, ast.NotIn are handled specially
}
UNARY_OP_DUNDERS: Dict[Type[ast.unaryop], Tuple[str, ...]] = {
ast.USub: ("__neg__",),
ast.UAdd: ("__pos__",),
# we have to check both __inv__ and __invert__!
ast.Invert: ("__invert__", "__inv__"),
ast.Not: ("__not__",),
}
class ImpersonatingDuck:
"""A dummy class used to create objects of other classes without calling their ``__init__``"""
# no-op: override __class__ to impersonate
class _Duck:
"""A dummy class used to create objects pretending to have given attributes"""
def __init__(self, attributes: Optional[dict] = None, items: Optional[dict] = None):
self.attributes = attributes or {}
self.items = items or {}
def __getattr__(self, attr: str):
return self.attributes[attr]
def __hasattr__(self, attr: str):
return attr in self.attributes
def __dir__(self):
return [*dir(super), *self.attributes]
def __getitem__(self, key: str):
return self.items[key]
def __hasitem__(self, key: str):
return self.items[key]
def _ipython_key_completions_(self):
return self.items.keys()
def _find_dunder(node_op, dunders) -> Union[Tuple[str, ...], None]:
dunder = None
for op, candidate_dunder in dunders.items():
if isinstance(node_op, op):
dunder = candidate_dunder
return dunder
def eval_node(node: Union[ast.AST, None], context: EvaluationContext):
"""Evaluate AST node in provided context.
Applies evaluation restrictions defined in the context. Currently does not support evaluation of functions with keyword arguments.
Does not evaluate actions that always have side effects:
- class definitions (``class sth: ...``)
- function definitions (``def sth: ...``)
- variable assignments (``x = 1``)
- augmented assignments (``x += 1``)
- deletions (``del x``)
Does not evaluate operations which do not return values:
- assertions (``assert x``)
- pass (``pass``)
- imports (``import x``)
- control flow:
- conditionals (``if x:``) except for ternary IfExp (``a if x else b``)
- loops (``for`` and ``while``)
- exception handling
The purpose of this function is to guard against unwanted side-effects;
it does not give guarantees on protection from malicious code execution.
"""
policy = EVALUATION_POLICIES[context.evaluation]
if node is None:
return None
if isinstance(node, ast.Expression):
return eval_node(node.body, context)
if isinstance(node, ast.BinOp):
left = eval_node(node.left, context)
right = eval_node(node.right, context)
dunders = _find_dunder(node.op, BINARY_OP_DUNDERS)
if dunders:
if policy.can_operate(dunders, left, right):
return getattr(left, dunders[0])(right)
else:
raise GuardRejection(
f"Operation (`{dunders}`) for",
type(left),
f"not allowed in {context.evaluation} mode",
)
if isinstance(node, ast.Compare):
left = eval_node(node.left, context)
all_true = True
negate = False
for op, right in zip(node.ops, node.comparators):
right = eval_node(right, context)
dunder = None
dunders = _find_dunder(op, COMP_OP_DUNDERS)
if not dunders:
if isinstance(op, ast.NotIn):
dunders = COMP_OP_DUNDERS[ast.In]
negate = True
if isinstance(op, ast.Is):
dunder = "is_"
if isinstance(op, ast.IsNot):
dunder = "is_"
negate = True
if not dunder and dunders:
dunder = dunders[0]
if dunder:
a, b = (right, left) if dunder == "__contains__" else (left, right)
if dunder == "is_" or dunders and policy.can_operate(dunders, a, b):
result = getattr(operator, dunder)(a, b)
if negate:
result = not result
if not result:
all_true = False
left = right
else:
raise GuardRejection(
f"Comparison (`{dunder}`) for",
type(left),
f"not allowed in {context.evaluation} mode",
)
else:
raise ValueError(
f"Comparison `{dunder}` not supported"
) # pragma: no cover
return all_true
if isinstance(node, ast.Constant):
return node.value
if isinstance(node, ast.Tuple):
return tuple(eval_node(e, context) for e in node.elts)
if isinstance(node, ast.List):
return [eval_node(e, context) for e in node.elts]
if isinstance(node, ast.Set):
return {eval_node(e, context) for e in node.elts}
if isinstance(node, ast.Dict):
return dict(
zip(
[eval_node(k, context) for k in node.keys],
[eval_node(v, context) for v in node.values],
)
)
if isinstance(node, ast.Slice):
return slice(
eval_node(node.lower, context),
eval_node(node.upper, context),
eval_node(node.step, context),
)
if isinstance(node, ast.UnaryOp):
value = eval_node(node.operand, context)
dunders = _find_dunder(node.op, UNARY_OP_DUNDERS)
if dunders:
if policy.can_operate(dunders, value):
return getattr(value, dunders[0])()
else:
raise GuardRejection(
f"Operation (`{dunders}`) for",
type(value),
f"not allowed in {context.evaluation} mode",
)
if isinstance(node, ast.Subscript):
value = eval_node(node.value, context)
slice_ = eval_node(node.slice, context)
if policy.can_get_item(value, slice_):
return value[slice_]
raise GuardRejection(
"Subscript access (`__getitem__`) for",
type(value), # not joined to avoid calling `repr`
f" not allowed in {context.evaluation} mode",
)
if isinstance(node, ast.Name):
return _eval_node_name(node.id, context)
if isinstance(node, ast.Attribute):
value = eval_node(node.value, context)
if policy.can_get_attr(value, node.attr):
return getattr(value, node.attr)
raise GuardRejection(
"Attribute access (`__getattr__`) for",
type(value), # not joined to avoid calling `repr`
f"not allowed in {context.evaluation} mode",
)
if isinstance(node, ast.IfExp):
test = eval_node(node.test, context)
if test:
return eval_node(node.body, context)
else:
return eval_node(node.orelse, context)
if isinstance(node, ast.Call):
func = eval_node(node.func, context)
if policy.can_call(func) and not node.keywords:
args = [eval_node(arg, context) for arg in node.args]
return func(*args)
if isclass(func):
# this code path gets entered when calling class e.g. `MyClass()`
# or `my_instance.__class__()` - in both cases `func` is `MyClass`.
# Should return `MyClass` if `__new__` is not overridden,
# otherwise whatever `__new__` return type is.
overridden_return_type = _eval_return_type(func.__new__, node, context)
if overridden_return_type is not NOT_EVALUATED:
return overridden_return_type
return _create_duck_for_heap_type(func)
else:
return_type = _eval_return_type(func, node, context)
if return_type is not NOT_EVALUATED:
return return_type
raise GuardRejection(
"Call for",
func, # not joined to avoid calling `repr`
f"not allowed in {context.evaluation} mode",
)
raise ValueError("Unhandled node", ast.dump(node))
def _eval_return_type(func: Callable, node: ast.Call, context: EvaluationContext):
"""Evaluate return type of a given callable function.
Returns the built-in type, a duck or NOT_EVALUATED sentinel.
"""
try:
sig = signature(func)
except ValueError:
sig = UNKNOWN_SIGNATURE
# if annotation was not stringized, or it was stringized
# but resolved by signature call we know the return type
not_empty = sig.return_annotation is not Signature.empty
if not_empty:
return _resolve_annotation(sig.return_annotation, sig, func, node, context)
return NOT_EVALUATED
def _resolve_annotation(
annotation,
sig: Signature,
func: Callable,
node: ast.Call,
context: EvaluationContext,
):
"""Resolve annotation created by user with `typing` module and custom objects."""
annotation = (
_eval_node_name(annotation, context)
if isinstance(annotation, str)
else annotation
)
origin = get_origin(annotation)
if annotation is Self and hasattr(func, "__self__"):
return func.__self__
elif origin is Literal:
type_args = get_args(annotation)
if len(type_args) == 1:
return type_args[0]
elif annotation is LiteralString:
return ""
elif annotation is AnyStr:
index = None
for i, (key, value) in enumerate(sig.parameters.items()):
if value.annotation is AnyStr:
index = i
break
if index is not None and index < len(node.args):
return eval_node(node.args[index], context)
elif origin is TypeGuard:
return bool()
elif origin is Union:
attributes = [
attr
for type_arg in get_args(annotation)
for attr in dir(_resolve_annotation(type_arg, sig, func, node, context))
]
return _Duck(attributes=dict.fromkeys(attributes))
elif is_typeddict(annotation):
return _Duck(
attributes=dict.fromkeys(dir(dict())),
items={
k: _resolve_annotation(v, sig, func, node, context)
for k, v in annotation.__annotations__.items()
},
)
elif hasattr(annotation, "_is_protocol"):
return _Duck(attributes=dict.fromkeys(dir(annotation)))
elif origin is Annotated:
type_arg = get_args(annotation)[0]
return _resolve_annotation(type_arg, sig, func, node, context)
elif isinstance(annotation, NewType):
return _eval_or_create_duck(annotation.__supertype__, node, context)
elif isinstance(annotation, TypeAliasType):
return _eval_or_create_duck(annotation.__value__, node, context)
else:
return _eval_or_create_duck(annotation, node, context)
def _eval_node_name(node_id: str, context: EvaluationContext):
policy = EVALUATION_POLICIES[context.evaluation]
if policy.allow_locals_access and node_id in context.locals:
return context.locals[node_id]
if policy.allow_globals_access and node_id in context.globals:
return context.globals[node_id]
if policy.allow_builtins_access and hasattr(builtins, node_id):
# note: do not use __builtins__, it is implementation detail of cPython
return getattr(builtins, node_id)
if not policy.allow_globals_access and not policy.allow_locals_access:
raise GuardRejection(
f"Namespace access not allowed in {context.evaluation} mode"
)
else:
raise NameError(f"{node_id} not found in locals, globals, nor builtins")
def _eval_or_create_duck(duck_type, node: ast.Call, context: EvaluationContext):
policy = EVALUATION_POLICIES[context.evaluation]
# if allow-listed builtin is on type annotation, instantiate it
if policy.can_call(duck_type) and not node.keywords:
args = [eval_node(arg, context) for arg in node.args]
return duck_type(*args)
# if custom class is in type annotation, mock it
return _create_duck_for_heap_type(duck_type)
def _create_duck_for_heap_type(duck_type):
"""Create an imitation of an object of a given type (a duck).
Returns the duck or NOT_EVALUATED sentinel if duck could not be created.
"""
duck = ImpersonatingDuck()
try:
# this only works for heap types, not builtins
duck.__class__ = duck_type
return duck
except TypeError:
pass
return NOT_EVALUATED
SUPPORTED_EXTERNAL_GETITEM = {
("pandas", "core", "indexing", "_iLocIndexer"),
("pandas", "core", "indexing", "_LocIndexer"),
("pandas", "DataFrame"),
("pandas", "Series"),
("numpy", "ndarray"),
("numpy", "void"),
}
BUILTIN_GETITEM: Set[InstancesHaveGetItem] = {
dict,
str, # type: ignore[arg-type]
bytes, # type: ignore[arg-type]
list,
tuple,
collections.defaultdict,
collections.deque,
collections.OrderedDict,
collections.ChainMap,
collections.UserDict,
collections.UserList,
collections.UserString, # type: ignore[arg-type]
_DummyNamedTuple,
_IdentitySubscript,
}
def _list_methods(cls, source=None):
"""For use on immutable objects or with methods returning a copy"""
return [getattr(cls, k) for k in (source if source else dir(cls))]
dict_non_mutating_methods = ("copy", "keys", "values", "items")
list_non_mutating_methods = ("copy", "index", "count")
set_non_mutating_methods = set(dir(set)) & set(dir(frozenset))
dict_keys: Type[collections.abc.KeysView] = type({}.keys())
NUMERICS = {int, float, complex}
ALLOWED_CALLS = {
bytes,
*_list_methods(bytes),
dict,
*_list_methods(dict, dict_non_mutating_methods),
dict_keys.isdisjoint,
list,
*_list_methods(list, list_non_mutating_methods),
set,
*_list_methods(set, set_non_mutating_methods),
frozenset,
*_list_methods(frozenset),
range,
str,
*_list_methods(str),
tuple,
*_list_methods(tuple),
*NUMERICS,
*[method for numeric_cls in NUMERICS for method in _list_methods(numeric_cls)],
collections.deque,
*_list_methods(collections.deque, list_non_mutating_methods),
collections.defaultdict,
*_list_methods(collections.defaultdict, dict_non_mutating_methods),
collections.OrderedDict,
*_list_methods(collections.OrderedDict, dict_non_mutating_methods),
collections.UserDict,
*_list_methods(collections.UserDict, dict_non_mutating_methods),
collections.UserList,
*_list_methods(collections.UserList, list_non_mutating_methods),
collections.UserString,
*_list_methods(collections.UserString, dir(str)),
collections.Counter,
*_list_methods(collections.Counter, dict_non_mutating_methods),
collections.Counter.elements,
collections.Counter.most_common,
}
BUILTIN_GETATTR: Set[MayHaveGetattr] = {
*BUILTIN_GETITEM,
set,
frozenset,
object,
type, # `type` handles a lot of generic cases, e.g. numbers as in `int.real`.
*NUMERICS,
dict_keys,
MethodDescriptorType,
ModuleType,
}
BUILTIN_OPERATIONS = {*BUILTIN_GETATTR}
EVALUATION_POLICIES = {
"minimal": EvaluationPolicy(
allow_builtins_access=True,
allow_locals_access=False,
allow_globals_access=False,
allow_item_access=False,
allow_attr_access=False,
allowed_calls=set(),
allow_any_calls=False,
allow_all_operations=False,
),
"limited": SelectivePolicy(
allowed_getitem=BUILTIN_GETITEM,
allowed_getitem_external=SUPPORTED_EXTERNAL_GETITEM,
allowed_getattr=BUILTIN_GETATTR,
allowed_getattr_external={
# pandas Series/Frame implements custom `__getattr__`
("pandas", "DataFrame"),
("pandas", "Series"),
},
allowed_operations=BUILTIN_OPERATIONS,
allow_builtins_access=True,
allow_locals_access=True,
allow_globals_access=True,
allowed_calls=ALLOWED_CALLS,
),
"unsafe": EvaluationPolicy(
allow_builtins_access=True,
allow_locals_access=True,
allow_globals_access=True,
allow_attr_access=True,
allow_item_access=True,
allow_any_calls=True,
allow_all_operations=True,
),
}
__all__ = [
"guarded_eval",
"eval_node",
"GuardRejection",
"EvaluationContext",
"_unbind_method",
]